DEST006118MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: March 18, 1953. Advertised March 1, 1956

GERMAN PATENT OFFICE

The invention relates to an electronic transmitter and receiver for telegraphic characters according to the start-stop alphabet, which consists of bistable multivibrators, a generator and a Start-stop circuit included. These toggle and start-stop circuits are controlled by means of relay cells.

Under a relay cell are several rectifier cells branching off from a common connection point to be understood with the same transmission direction.

In the receiver, some of the bistable flip-flops serve as a memory; a scanning device controls each memory via a conductor that connects to the outputs of two relay cells of opposite polarity connected is. The relay cells are on the one hand via one and the same conductor from one to be taken over Polarity and, on the other hand, to start up the scanning device via individual conductors from Current surges of a polarity corresponding to the relay cell in question, with the theoretical duration of a drawing step occur in the same time periods, controlled.

The polarity of a relay cell is called positive or negative if the rectifier cells are their Passage direction from the common connection

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point from or to the communal connection point and the communal Connection point connected through a resistor to a positive or negative pole of a battery is.

Such a transmitter or receiver has already been proposed. The proposed sender or receiver has in addition to the above-mentioned components also an electronic distributor, which at least so

ίο Has a lot of tubes, as there are drawing steps are. For a sender or receiver for graphics characters In the five-step start-stop alphabet, the number of components is as follows: seven bistable Multivibrators, a generator and a start-stop circuit and a distributor for the seven steps a telegraph sign.

In the transmitter or receiver according to the invention, the number of different components is on three have been reduced, namely they contain when using characters in the five-step start-stop alphabet the following circuits: ten or nine bistable multivibrators, one generator and one Start-stop circuit. The distributor for the seven character steps is therefore omitted. The simpler structure is an advantage in manufacturing.

According to the invention, this simple structure has been achieved that in the transmitter or in the receiver the polarity of an output of each previous flip-flop at the same instant by means of the The above-mentioned scanning device controls the input of the flip-flop that follows it (so-called Sliding method). The required current surges are supplied by one of the bistable multivibrators, this itself being controlled by positive power surges from the generator, from the second and following, because the first positive current surge from the generator is conducted by means of relay cells is that the flip-flops of the memory all assume a certain state, namely in Sender according to the polarities of the character to be sent and in the receiver accordingly of positive polarity, except that the first circuit, GSVII, is set to negative polarity, after which on the second rush of the Generator the above-mentioned scanning and shifting process begins, with the first flip-flop in the transmitter of the series, SSVII, is always controlled by the negative polarity and the last flip-flop of the series, SSI, is used to send the steps and where in the receiver the first flip-flop of the series, GSVII, controlled by the polarities of the successive incoming steps of the sign and the criterion for ending the scanning and shifting process in the setting of a receiver flip-flop or several transmitter flip-flops.

It is noted that the idea, given a number of circuits with two possible states in At certain moments, each circuit uses current surges to change the state of the previous one To take over circuit, is known per se. This can be found in the shift register of calculating machines Thought application. Either an auxiliary register is used here, so that a double Series of circuits and corresponding current surges are necessary at different moments, or a delay circuit, the takeover by means of a two-way supply of current impulses he follows.

Transmitter and receiver according to the invention and those according to the older proposal can be in Self-connecting teletype networks are used. The caller should be able to do this by sending a number to establish the connection with the desired subscriber during the exchange should be able to automatically send back characters for identification.

Transmitter and receiver according to the invention as well as those according to the older proposal can can also be used in TOR systems (Teleprinting Over Radiocircuits) as so-called extenders. In such a TOR system, the telegraphing steps arriving one after the other via a line per character z. B. five steps simultaneously from such an extensor for an alphabet conversion fixed and after this implementation z. B. in seven step characters in this form one after the other second extensor dispatched again.

The invention will now be described in more detail with reference to the drawings. go

Fig. Ι shows a telegraph character in the expanded Five-step start-stop alphabet;

2 shows the so-called normal circuit (special flip-flop circuit) which is used for the components IS, IV, VS, GSI to GSVII and SSI to SSVII;

Fig. 3 plots grid current and voltages at various points in the normal circuit as a function the input voltage;

Fig. 4 shows the start-stop circuit; Fig. 5 shows the generator circuit;

Fig. 6 shows voltages at various points in the generator circuit as a function of time;

Fig. 7 shows how the steps of a received character by the flip-flops GSI to GSVII migrate the recipient;

8 and 8 'give the circuit diagram of the receiver, in which ¹ the circuits already shown individually are shown as small rectangles;

Fig. 9 shows how the steps of a character to be sent by the shift circuits SSI to SSVII wander the transmitter;

Fig. 10 and 10 'give the circuit diagram of the transmitter, in which the circuits already shown individually are shown as small rectangles.

The figures are for the case of the use of telegraph characters of the extended five-step start-stop alphabet drawn. From the given description, however, circuits for characters can easily be drawn can be derived in a start-stop alphabet with a different number of group steps.

The characters that are used in communication between jump writers each consist of seven Steps, if the start and stop steps are counted, with each step having a duration of 20 ms (Fig. 1).

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The first step of the telegraph sign, the so-called start-up step, is always a negative one Drawing step; This initial step is followed by the alphabet steps, which consist of five character steps. Each drawing step can have a positive or a negative character. Then the locking step follows, which is always positive.

The recipient is now considered first. The recipient will go through the initial step of the incoming

jo left the character. With regard to disruptions the start-up step in the line must be longer than 10 ms to start the receiver. If the recipient takes an incorrect start-up step (shorter than io ms), he should immediately be able to neglect a new wrong start-up step or to address a correct start-up step in the correct way.

The receiver is composed of the following components:

ao i. an input circuit / S, which is used to to provide the received character with right-angled edges and the amplitude a certain To give value;

2. a start-stop circuit SSS for starting ', 5 and stopping the generator;

3. a generator circuit G for 50 Hz, which, with each receiver cycle, first supplies a current impulse to the memory GSI and the following current impulses to the pulse amplifier IV;

4. a pulse amplifier IV, which at the right moments causes the polarities of the successive steps of the symbol to determine the state of a flip-flop GSVII and at the same time each of the flip-flops GSI to GSVII connected in series to take over the state of the previous circuit;

5. seven flip-flops GSI to GSVII, the states of which indicate the polarities after receiving the character specify the steps of the received character, namely GSI gives the start-up step, GSII to GSVI the Group steps and GSVII the locking step. GSI also serves as an auxiliary circuit when starting and shutdown, sets the flip-flops GSII to GSVII in the required initial states when starting and controls the current surges of generator G through its state.

The transmitter contains the components mentioned at the receiver under 2 and 3 in the sense that the generator circuit G first supplies the shift circuit SSVII with a current pulse and the pulse amplifier IV with the following current pulses during each transmission cycle, and continues

6. an input circuit / S, which serves as an auxiliary circuit when starting;

7. an amplifier circuit VS, which serves as an auxiliary circuit for starting and stopping and controls the current surges of the generator G through its state; 8, a pulse amplifier IV which sets the shift circuit SSVII in the negative state and

■ 60 each slide switch in the right moments causes in the series SSI to SSVI to take over the state of the previous circuit ;

9. seven shift circuits (flip-flops) · SSI to SSVII, whose states one at the beginning Cycle to be determined by the character to be sent; SSI sends the characters.

The center scanning of the takes place in the receiver 30 ms after the beginning of a correct start-up step first drawing step of the character. A subsequent character step is then scanned every 20 ms. The result of the scans is stored in five flip-flops.

The duration of the receive cycle must be shorter than 140 ms, so that when receiving consecutively The recipients match characters sent by a too fast-running transmitter with this transmitter Can keep up. The size of the shortening of the reception cycle is due to the speed deviation to be compensated conditional. A greater shortening than is necessary for this reason has the disadvantage that the equalization capability of the receiver decreases.

For the electronic recipient, the duration of the Receive cycle on. set a minimum of 130 ms will.

A description of the constituent parts shown as rectangles in FIGS. 8 and 8 'now follows the description the actual construction beforehand.

A toggle switch is used for the components / S, IV and GSI to GSVII. This flip-flop (Fig. 2) consists of a double triode Bi ₁₁ , Bi ₆ , a number of resistors and two glow lamps L ₁ , L ₂ . The tubes Βτ _α and Si ₆ have a common cathode resistance R _lb , which is connected to the negative pole of the battery V. The parallel connected resistors R ₁ and R ₂ or i? ₄ and R _{6 are} provided, which are connected to the positive terminal of the battery V. A voltage divider RJR ₁₁ or R ₉ JR ₁₉ , the other end of which is connected to the negative pole of the battery V , is connected to each anode. The taps 9 and 4 are the output terminals. The resistors R ₁₂ and A ₁₈ are connected in series between the output terminals; the connection point between these resistors is point 6. Furthermore, two high-resistance voltage dividers RJR ₁₆ and RJR _{11 are} attached, which are connected in parallel with voltage dividers RJR ₁₁ and R _9, JR _19. The tap of the voltage divider RJR ₁₆ is connected to the control grid of the tube -Bi ₆ and at the same time via resistor R ₁₇ to point 6.

The tap 5 of the voltage divider RJR _U is connected to point 6 via resistor R _13. The control grid of the tube Βτ _α is connected to point 8 and via resistor R ₁₀ to point 7. The anode of the tube Bi _a is connected to point 10 and the anode of the tube Bi ₆ to point 3. The glow lamps L ₁ and L _{2 are also} connected to these points; they are fed from the positive pole of the battery V through resistor R _3.

If the control grid of the tube Bi _{0 is} strongly negative with respect to the cathode, this tube does not carry any current; A positive voltage is applied to the control grid of the tube .Bi ₆ via the voltage divider RJR _le . The tube Bi ₆ is then conductive; the anode

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voltage of this tube is lower than that of tube Bi ₀ ; the glow lamp L ₂ lights up, L ₁ does not. The output terminal 9 has a higher voltage than the output terminal 4. The output terminal 6 has a voltage that is halfway between the voltages of the output terminals 9 and 4 (negative state). Now 'increases the potential of the control grid of the tube Bi _a, so at a certain value of this potential, these tube whereby the tube B becomes nonconductive I ₆ becomes conductive. The glow lamp L ₁ ignites, L ₂ goes out. The output terminals 9 and 4 change the voltage (positive state). The circuit is dimensioned in such a way that the transition from one position to the other takes place abruptly with a small change in the input potential at point 7. In the two layers of the circuit, point 6 always has the same voltage because the resistors R ₁₂ and i? _{18 are the} same. If the input terminal 7 has a voltage which is almost the same as the voltage of point 6, the circuit changes position.

If the value of the resistors R ₁ , R ₂ , R _it A ₅ , R ₆ , R ₉ , R ₁₁ , R ₁₂ , R _ls and R ₁₉ = 39 kü and that of R ₇ , R _s , R ₁₃ , -R ₁₄ and R ₁₆ = ι ΜΩ, from R ₃ = 820 LQ, from R ₁₀ = 470 kü, from R ₁₅ = 15 kü and from R ₁₇ = 270 kü and a battery V with a voltage of 220 volts and a grounded negative pole is used, the output terminals 9 and 4 at an input voltage which is lower than 70 volts, a voltage of 80 and 60 volts. Terminal 6 has a voltage of 70 volts. If the input voltage is increased, the output voltages change at an input voltage of around 70.5 volts and assume values of 60 or 80 volts. If the input voltage is increased further, the output terminals retain almost the same output voltages. If you lower the input voltage, the circuit returns to its original position at around 69.5 volts.

In Fig. 3 the grid current of tube Bi _a and voltages at various points in the circuit are shown as a function of the input voltage. If output terminals 9 and 4 are loaded, the voltages at these terminals will change, and at the same time the voltage at point 6 will change.

As a result of the coupling of the control grid of the tube Bi _b via resistor R ₁₇ with point 6, a change in the input voltage also occurs in this case, the circuit changing position in such a way that the input voltage is always halfway between the voltages of the output terminals 9 and 4 lies.

If several circuits are to work together, the points 6 are connected to one another, whereby the voltage levels become equal as much as possible.

The output terminal 5, which is high-resistance, can be connected to the input terminal 7, whereby the position of the circuit is maintained after the controlling input voltage is removed is. The normal circuit has now become a so-called memory circuit.

The generator and the start-stop circuit

The generator circuit is a normal multivibrator circuit with a frequency of 50 Hz. The start-stop circuit is used to start the generator to start at the beginning of a character and to stop at the end of a character.

In Fig. 4 and 5, the start-stop circuit and the generator circuit are shown.

There is a double triode in each circuit.

The values of the resistances are in Fig. 4: R ₂₀ = R ₂₃ = 1.2 ΜΩ; R ₂₁ = 820 kü; R ₂₂ = 27 kΩ; and in Fig. 5: # ₂ 4 = ^ ₂₆ = R ₃₀ = R ₃₁ = 10 kβ; R ₂₆ = 680 kÜ; = R _M = i ΜΩ; R _2B = R ₃₇ = 56 kÜ;

= R ₃

= 270 kü ; R ₃₃ = R _3i = 39 ku ; R ₃₆ = R ₃₉ = 560 kü and A ₃₈ = 47 kü.

Capacitors C ₁ and C ₂ (Fig. 5) are approximately 20,000 pF. The voltage at the cathode of the double triode in the start-stop circuit is approximately 70 volts. When the control grid of the tube B2 _a a voltage lower than 70 volts, so that tube leads 8a no electricity; consequently, the tube Bz _b carries current. In the anode lead of this last tube, the resistance is i? _{27 of} the generator circuit added.

As a result, the control grid of the tube B ^ _{a of} the generator has the same negative potential with respect to the cathode that it has when the tube B ^ _a is non-conductive during the action of the multivibrator. The control grid of the tube B ^ _{b of} the generator is connected to a positive voltage _{via the resistors A 34} and R _29. This tube is conductive; the glow lamp L ₁ is ignited. The capacitors C ₁ and C ₂ are charged to the same voltages.

If the voltage at the control grid of tube B2 _{a of} the start-stop circuit is increased, this tube becomes conductive and tube B2 _b non-conductive at approximately 70 volts grid voltage. The capacitor C ₁ now discharges through resistor A ₂₇ ; the control grid voltage of the tube B3 _α increases. After 10 ms this tube becomes conductive; the voltage drop in the 100th anode lead is via capacitor C ₂ after the control grid of the. Transfer tube B $ _b , blocking that tube. The capacitor C ₁ will now. Charged quickly to the original high value via the anode resistors R ₂₆ and R _n. Due to the discharge of the capacitor C ₂ via the resistor R _{29, the} control grid of the tube i? 3 ₆ reaches the potential of the cathode again after 10 ms, whereby this tube becomes conductive again and the tube B _a non-conductive, etc., 110.

To stop the generator, the tube B2 _{a of} the start-stop circuit must be brought back into the non-conductive position by bringing the control grid voltage below 70 volts. If the tube B2 _{a of} the start-stop circuit becomes conductive for a period shorter than 10 ms, the tubes of the generator do not change their state. However, this period of time can, if necessary, be shortened or lengthened in two ways, namely firstly by selecting the various switching elements in such a way that when tube B2 _{b is live,} the control grid of tube B ^ _a receives a higher or a lower potential, as this grid has during the action of the multivibrator in the closed position of the tube B ^ _a , or secondly, by taking 12s the values of the capacitors C ₁ and C ₂ . not equal

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takes, but in such a way that the multivibrator still works with a frequency of 50 Hz.

In Fig. 6 the potentials of points 3 and 8 of the circuit according to FIG. 5 are shown in the upper half, and the potentials of points 10 and 5 of this circuit are shown in the lower half, all four as a function of time, namely for the duration of a whole character. The difference between the potentials of points 3 and 8 represents the voltage on capacitor C ₁ , the difference between the potentials of points 10 and 5 represents the voltage on capacitor C _2. The potential of the cathode of the generator is indicated by a dash-dot line specified. Also shown in Fig. 6 with dashed lines is what takes place in the event of an incorrect start-up step,

The frequency of the generator can be adjusted using the resistor R _i0. The glow lamps L ₃ and L ₁ indicate which tube is conductive.
Referring now to FIGS. 8 and 8 ', the receiver

ao described. These are the ones described above Components shown as small rectangles for the sake of simplicity; the digits in these rectangles correspond to the digits in the previous figures, it is primarily to be noted that the Points 6 of the circuit are grounded. This gives the input level, with each flip-flop the Changes position, brought to earth potential; have the output voltages. Values of -j-10 volts and -10 volts to earth. The + terminals have one

Voltage of +150 volts and the terminals a

Voltage of -70 volts to earth.

The circuits / S, IV, GS1 to GSVII are normal circuits according to FIG. 2. The circuit SSS is designed according to FIG. 4 and the circuit G according to FIG.

The incoming character is sent via the input terminal I to the sieve grille (point 7) of the input circuit IS . In the rest position, the input terminal has a positive voltage to earth.

In FIG. 7, the characters in the first column (to the left of the line PQ) indicate the states of the flip-flops indicated next to them for the rest position; the status of GSI corresponds to the polarity of the start-up step (-), the statuses from GSII to GSVI correspond to the polarities of the character steps (+ or -, indicated in small circles) of the last received character. The state of GSVII corresponds to the polarity of the locking step (+).

If a character is now received, the following proceeds (see Fig. 7): If the starting ρ polarity is at the input terminal for 10 ms, the circuits GSI to GSVI are in the positive state and GSVII in the negative state. 20 ms later, the first group step of the character is scanned and taken over by GSVII. At the same time, GSVI takes over the previous status from GSVII; in the same way GSY takes over the previous state of GSVI etc. The result is that the flip-flops GSI to GSY remain in the positive position, GSVI assumes the negative position and GSVII indicates the polarity of the first group step of the incoming character.

This scanning and shifting process is repeated at intervals of 20 ms; so the character in the seven flip-flops are stored. The polarities can change 130 ms after the start of the startup step of the five alphabet steps can be taken from the flip-flops GSII to GSVI at the same time. I the Device according to the older proposal, the seven-fold distributor ensured that the recipient always a cycle corresponding to the reception of a single Made sign. In the device according to the invention, the criterion for a cycle is that 10 ms after the start of the start-up step GSI comes into the positive position and 120 ms in this position remains, after which the initial step of the sign is pushed from GSVII to GSI and the recipient comes to a standstill.

The effect of the receiver is now examined in detail with reference to FIG. 8: Point a, which is connected to output terminals 9 and IS _{or GSI via rectifiers G 1} and G ₃ , assumes the more negative of the voltages of these two points and is thus negative in the rest position. Point b, which is connected to point α _{or terminal 4 of GSI via rectifiers G 4} and G ₅ , assumes the more positive of the voltages of these two points, so it is also negative. The tube Σ> 2 _{α of} the start-stop circuit SSS is therefore non-conductive, and the generator G is at a standstill; the flip-flops remain in the same state. The control grid, point 7 of the pulse amplifier IV, which is connected to point k or _{the output terminal 4 of GSI via rectifiers G 6} and G ₇ , assumes the more negative of the voltages of these two points and is therefore negative.

If a character arrives, the input terminal I is negative as a result of the start-up step; Point a becomes positive and thereby also point b. After 10 ms the state of the generator tubes changes; the generator supplies a positive current surge to the input of GSI via capacitor C _3. As a result, GS I comes into the + position and leads via: C _{6 to} the connection point between resistors. ^ And i? ₄₅ a positive and via C ₄ the connection point between resistors i? ₄₂ and i? _{43 to} a negative power surge. The positive current surge is passed on via rectifier cells G ₁₉ , G ₂₇ , G ₃₅ , G ₄₃ and G ₆₁ to points 7 of the trigger circuits GSII to GSVI. So these come into the positive state. The negative current surge is passed on to the radio 7 of the flip-flop GSVII _{via the rectifier cell G 60.} ι10 This assumes the negative position .. The transition from GSI to the positive position also has the consequence that terminal 4 is now positive, that is, point b is also positive, regardless of the voltage at point a, that is, regardless of polarity the input terminal I. The generator continues to work as long as GSI is in the positive position. Because GSI is in the positive position, the following positive current surges from generator G can no longer influence point 7 of circuit GSI, since _{a negative output terminal is reached via G 9} and R _M , but point 7 of pulse amplifier IV, there A positive output terminal is reached via G ₇ and O _47.

30 ms after the input terminal has become negative, the generator gives the second positive

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Current surge from; the negative current surges between two positive ones have no effect.

The second positive current surge is passed on to the pulse amplifier, which for a moment the state changes and thus a positive via output terminal 4 and via the output terminal 9 emits a negative current surge, which. after seven scanners that each consist of six rectifiers, such as B. the at

ίο GSII from G ₂₀ to G _2B .,.

The effect of these scanning devices can e.g. B, for GSII are explained as follows: GSII like GSI and GSIII to GSVII have become a bistable trigger circuit by attaching the connection between points 5 and y. The output terminals 9 and 4 of the pulse amplifier IV have the negative

., This device has a voltage of +10 volts or -10 volts to earth. The voltage of points is equal to the more negative of the voltages of output terminal 4 (of IV) and point «. Regardless of the voltage at output terminal 4 of GSIII, point c has a negative voltage as long as output terminal 4 (of IV) remains negative. Point d has a voltage which is equal to the more positive of the voltages of points 9 (of IV) and β , and since 9 (of IV) is positive, point d has a positive voltage to earth. This voltage is also independent of the voltage of the output terminal of GSIII as long as terminal 9 (of IV) remains positive. The rectifying

cells G ₂₀ and G ₂₁ are non-conductive; the connection point f can assume any potential between +10 volts and -10 volts. The flip-flop GSII can, for this purpose, be in either of the two states.

If the pulse amplifier IV now outputs a positive current impulse via the output terminal 4 and a negative current impulse via the output terminal 9, then if the output terminal 4 of GSIII and thus point e is positive, point c becomes positive; Point d remains positive.

Since GSII is in the positive position, it remains in that position. But if it is in the negative position, it is brought into the positive position _{via the rectifier cell G 20.}

But if the output terminal 4 of GSIII is negative, point c remains negative and d becomes negative. GSII is then brought from the positive to the negative position via rectifier cell G _21. 30 ms after the input terminal has become negative, the flip-flop GSVl takes over the polarity of GSVII, GSY that of GSVI etc. as a result of the current surges of the pulse amplifier IV , while GSVII takes over the polarity of the output terminal 4 of the input circuit IS, i.e. the polarity of the first group step , takes over. The delay circuit connected to the output of a trigger circuit, e.g. B. R _i9 jCc, with GS III ensures that the old output polarity of the flip-flop is maintained for a moment after the flip-flop itself has assumed the new state

has; this enables the previous polarity to be adopted.

There is now a shift every 20 ms, as indicated in FIG. 7. 120 ms after GSI has come into the positive position, this' circuit takes over the negative polarity of the start-up step. Point b is now negative, regardless of the polarity of input terminal I. Terminal 4 of GSI is immediately negative. Point g was negative and remains negative for some time due to the delay circuit. As a result, point α also remains negative. The generator immediately comes to a standstill and resumes its rest position. After a period of time, adjustable by the size of capacitor C ₆ and resistor R _le , point α comes back under the control of input terminal I. If this terminal is supplied with a negative voltage, the generator starts up again; however, it remains in the rest position as long as the input terminal is positive. By making the delay e.g. If, for example, it is set to 5 ms, it is again possible to receive a following character 135 ms after the start of the start-up step. If the input terminal becomes negative before the end of this period due to the distortion of the character, the receiver waits until this 135 msec has ended and only then begins a new cycle.

When stopped, the seven flip-flops are set according to the polarities of the steps of the received character. The polarities of the group steps can then be taken from outputs II to VI. For this purpose, these outputs are controlled by an equal number of relay cells with positive polarity. Of these relay cells, one rectifier cell is always connected to output terminal 4 of the relevant flip-flop and the other to output terminal 9 of GSI. For GSII z. B. these are G ₈₈ and G ₈₇ . It is clear that the polarity of output terminal 4 is taken over by the output as soon as G _{87 is provided} with a positive polarity, ie as soon as GSI comes into the negative position.

This is the right moment; the output terminals 4 then have the polarities of the group steps of the received character. While the rest of the time there is negative polarity at the outputs.

The further processing of the sign is not part of the invention. When receiving a following Character, the previous character is deleted and replaced by the new one.

Output VII takes the polarities of all steps of the received one after the other with intervals of 20 ms Character and can, where desired, be used to forward this character ^ rectified, whereby the receiver can also serve for equalizing transmission. • In order to ensure a good effect for the recipient under all circumstances, two so-called Interlocks are provided. The first for GSVII provided locking is to prevent this circuit assumes a negative position when the Input terminal is positive and the receiver is at rest. When used as a The equalizing transmission would then have a negative instead of a positive polarity via output VII to the outgoing line. This case could occur if the input terminal

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Is negative for 140 ms, ζ. Β. through the uninterrupted reception of character steps such as the final signaling. The last scan is then negative and the receiver does not make a new cycle. The rectifier cells G ₆₉ , G ₆₅ , G ₆₈ and G ₆₉ are now there. In the rest position, G ₆₅ , G ₆₉ and G _{68 are} all provided with positive polarity. Even if the last scan was negative, after an adjustable period of time, e.g. B. 10 ms corresponding to the size of C ₁₄ and i? ₅₆ ; Point i also positive, which means that point h must also become positive and GSVII must come into the positive position _{via G 59.} When starting up and during the rest of the cycle, it is no longer true that G ₆₅ , G ₆₉ and G _{68 are} all provided with a positive polarity, so that the interlock is canceled. . .

The second lock provided at GSI is to prevent all flip-flops, including GSI, z. B. when putting the receiver into operation by chance circumstances assume the positive situation. As a result, the generator would start up, and with a positive input voltage, the result of the sampling by GSVII would always be positive, so that the receiver would no longer come to a standstill. Now, however, the rectifiers G ₁₁ , G ₂ , G ₁₈ , G ₂₆ , G ₃₄ , G ₄₂ , G ₅₀ and G _{58 are} provided, which means that when the input terminal I is positive and the flip-flops GSII to GSVII are in the positive position , Point ./ becomes negative and therefore GSI must be supplied with a negative input voltage _{via G 11.} When starting up and during the rest of the cycle, it is no longer true that G ₂ , G ₁₈ , G ₂ , - ,, G ₃₄ , G., 2, G ₅ J, and G _{58 are} all provided with a negative polarity, so that the Lock is released.

Fig. 10 and 10 'shows the circuit diagram of the transmitter. The components already described are shown as small rectangles. Points 6 of the circuits are grounded again. The circuits / S, FS, IV and SSI to SSVII are circuits according to FIG. 2. The circuit SSS is designed according to FIG. 4 and the circuit G according to FIG.

The transmitter starts up by applying a negative current impulse of at least 10 ms to the starter terminal S. In FIG. 9, the characters in the first column indicate the states of the shift circuits indicated next to them in the rest position. If terminal S is positive for 10 ms, proceed as follows (see Fig. 9): SSI is in the negative position, SSVII in the positive. Position, and SSII to SSVI are set according to the polarities of group steps 1 to 5 of the character to be sent. 20 ms later, SSVII gets into the negative position, and at the same moment SSVI takes over the previous position from SSVII, SSY that of SSVI, etc. The transmitter works according to the same scanning and shifting method as the receiver, in the sense that with SSVII transmitter is always held in the negative position. 130 ms after S has become negative, the transmitter is again in the rest position; During this period, the entire character could be taken from SSI's Z output terminal. The criterion for a cycle is that 130 ms after S has become negative, the shift circuits SSII to SSVII are in the negative position.

The effect of the transmitter will now be described in detail with reference to FIG. 10: After a negative current surge of at least 10 ms at the starter terminal S, the tubes of the generator G change their state in the manner already described for the receiver. It then goes through a positive surge _C3 to the input terminal of SS VII. This terminal, which was only negative is now positive. Point k becomes positive because the two rectifier cells G ₇₁ and G _{72 are provided} with a positive polarity. In the rest position VS was in the negative position, as will be seen later, and thanks to the delay circuit C ₁₇ , A ₅₇ , G ₇₂ remains provided with positive polarity for a moment. SSVII is therefore in the positive position. As is the case in the receiver at GSI, the transmitter SSVII now emits a negative or a positive current surge _{via C 15} and C _16. The negative rush current puts SSI in the negative position. The positive current impulse causes the input terminals from SSII to SSVI to adopt the polarities of the input terminals II to VI, which are also the polarities of the group steps of the character to be sent. .

How these input terminals get these polarities does not belong to the invention. If we look again in particular z. B. the state at input terminal II, it is found that the positive current surge that _{arrives at G 78} , makes it possible that the input terminal 7 of SSII is also positive when input terminal II is positive. But if input terminal II is negative, input terminal 7 of SSII remains negative. The amplifier circuit FS, which is in the negative state in the rest position because the rectifier cells G ₈₇ to G ₉₂ on the side not connected to input terminal 7 are all provided with a negative polarity, now comes into the positive position. G ₉₂ received positive polarity as a result of the change in state of SSVII. The change in state of VS causes, on the one hand, that input terminal 7 of the start-stop circuit is now positive due to the connection to output terminal 4 of VS , even if the start-up current surge has ceased. On the other hand, it causes. that the following positive current surges from generator G can no longer influence the input terminal of SSVII. Point k is always negative during the further cycle, since the negative polarity of output terminal 9 of VS is applied _{to rectifier G 72} after an adjustable delay corresponding to the size of capacitor C ₁₇ and resistor A _57. Likewise after an adjustable delay, determined by the size of capacitor C ₁₈ and resistor i? ₅₈ , these current surges can now reach the input terminal 7 of the pulse amplifier IV . Since VS was in the negative state in the rest position, IV was also in this state, since G ₇₀ and G _{74 were provided} with a negative polarity; So point 1 was negative. With every positive current surge from the generator, IV- comes in for a moment

509 660/346

St 6118 VIII a / 21a ¹

the positive situation; G ₇₄ now has a permanently positive polarity, G ₇₀ during the current surge.

At this moment IV supplies output terminal 9 with a negative and output terminal 4 with a positive current surge. In the same way as was discussed with the receiver, this causes that every time after a period of 20 ms the shift circuit SSVI takes over the state of SSVII, SSV that of SSVI, etc. In the case of shift circuit SSVII, however, the position is now such that point k is permanently negative while output terminal 9 of IV provides negative current surges. The first negative current surge from IV thus sets SSVII into the negative state, which is maintained for the further duration of the cycle.

So the character pushes through the sender of

right to left, followed by states. When

the shift has progressed so far that SSII to SSVII have assumed the negative position, input terminal 7 of VS becomes negative again. - So VS comes into the negative position. The blocking step of the sent character has now also just arrived at the output terminal Z of SSI. Since VS has now entered the negative position, the generator immediately comes to a standstill, which is achieved again in the same way as with the receiver. Of the rectifier cells provided at input terminal 7 of SSS, one on the other side is immediately provided with negative polarity; the other remains connected for a moment to a point with negative polarity. After a set time ¹ space, determined by the size of capacitor C ₁₇ and resistor R _57, the generator can start again here. If the transmitter works for itself and so S is continuously held negative, the duration of the transmitter cycle is set to 140 ms. If characters are sent again, this period can be reduced to 135 ms _{by changing the size of C 17} and R ₅₇ , if desired.

In order to ensure that the transmitter works properly under all circumstances, a lock is fitted here as well as with the receiver. This is to prevent the shift circuit SSI from getting into the negative position in the rest position. A negative instead of a positive polarity would then be applied to the outgoing line. Now, however, the rectifier cells G ₇₃ and G _{93 are} provided, which in the rest position are both provided with terminals of positive polarity, namely terminal 9 of VS and terminal 4 of IS, so that point m is positive and SSI via G ₉₄ must come into the positive position.

When starting up and during the rest of the cycle, it no longer applies that G ₇₃ and G _{93 are provided} with a positive polarity, so that the interlock is canceled.

Whichever embodiment the inventive idea may assume, it is always essential that in Transmitter and receiver change the polarity of an output of each previous flip-flop in the same Momentarily the input of the flip-flop circuit following it by means of a scanning device mentioned above controls. This shifting process is started and ended for a time, namely started 30 ms after the start of the application of a negative voltage to the starting terminal S or the input terminal I, and terminated when the shift process has taken place six times.

Claims (2)

PATENT CLAIMS: 1. Electronic transmitter and receiver for telegraphic characters according to the start-stop alphabet, which as components of bistable multivibrators, a generator and a start-stop circuit included, the control of these toggle and start-stop circuits is carried out by means of relay cells and in particular in the receiver some of the bistable multivibrators are designed as memories is, and a scanning device is used which has such a memory circuit controls via a conductor, with which the outputs of two relay cells opposite forward direction are connected, on the one hand via one and the same conductor from one to be taken over Polarity and, on the other hand, for starting the device via individual conductors of current surges a polarity corresponding to the relevant relay cell, which corresponds to the theoretical duration of a Character steps occur in the same time periods, are controlled, characterized in that in the sender and receiver the. Polarity of an output of each preceding multivibrator im at the same moment the input of the following by means of a scanning device mentioned above Toggle switching controls (so-called shifting method), whereby the required current surges are supplied by one of the flip-flops and this circuit itself by positive ones Current surges from the generator is controlled, namely from the second and subsequent because the first positive current surge from the generator is conducted by means of relay cells so; that the flip-flops all assume a certain state, namely in the sender according to the 'polarities of the character to be sent and in Receiver according to the positive polarity, except that the first circuit (GSVII) is set according to the negative polarity, after which the second current surge of the generator the above-mentioned scanning and shifting process begins, with the first flip-flop in the transmitter of the series (SSVII) is always controlled by the negative polarity and the last flip-flop the Row (SSI) to. Sending the steps is used and where the recipient is the first Toggle circuit of the series (GSVII) of the polarities of the successive incoming steps of the Character is controlled and the criterion for ending the scanning and shifting process in the There is a setting of a toggle switch in the receiver or several toggle switches in the transmitter. 2. Electronic transmitter and receiver according to claim 1, characterized in that locking devices are provided to prevent certain bistable multivibrators 660/346 St 6118 VIIIal21a ¹ assume a wrong position with respect to polarity, with such a locking device from a relay cell with the correct idle state of the toggle switch to be locked corresponding polarity exists, while further a rectifier of this relay cell, the flip-flop circuit controls and all other rectifiers of this relay cell when the transmitter is idle and of the receiver, but only in this, are provided with the same desired polarity. For this purpose 3 sheets of drawings