DEST008063MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Filing date: April 17, 1954. Advertised on January 26, 1956

GERMAN PATENT OFFICE

A device is known by means of which two messages originating from two subscribers A and B can be transmitted simultaneously over a channel, the message from subscriber A being intended for a subscriber C and the message from B for a subscriber D.

This device is provided with switching means which automatically send the characters from A and the characters from B into the channel on one side, the characters being automatically provided with an identifier which indicates whether the characters originate from A or from B. On the receiving side of the channel means are provided which automatically differentiate the characters of the message for subscriber C from the characters of the message for subscriber D and the characters of the message for subscriber C automatically according to subscriber C and the characters of the message for subscriber D automatically according to subscriber Send D. The telegraph speed is half of the maximum speed that can be achieved in a channel. Means are also provided which, if either A or B alone sends a message, automatically make the channel available only to A or only B , in which case it is possible to work at full telegraphing speed.

In this device, however, with a view to good distribution, there are a number of additional ones

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Characters required. The transmission of these additional characters takes a long time, because "at most only with half the telegraph speed of the main channel can be worked.

These difficulties are eliminated in the device according to the invention. At the device according to the invention, each character is preceded by an additional step. One sign

ίο from A goes z. B. a step ahead with positive polarity, while a sign of B is preceded by a step with negative polarity. The polarity of the -, additional step is determined by the device itself and given automatically.

The device according to the invention will now be explained with the aid of a few figures.

Fig. Ι and 2 give the circuit diagram of the transmitter; Fig. 3 gives. some timing diagrams;

Fig. 4 gives the circuit diagram of the receiver.

The transmitter will now be described first. At A (Fig. 1), the message from subscriber A for subscriber C is fed to the device by means of a perforated tape in the five-step alphabet. At B , the message from subscriber B for subscriber D is supplied in the same way.

If subscriber A has a message, he makes contact ςΑ; if subscriber B has a message, he closes contact q ² .

There are now three options: i. Subscriber A alone sends a message. 2. Subscriber B alone sends a message. 3. Both participants send a message at the same time.

If A alone has a message to send, he closes contact q ¹ . A current then flows from the battery via winding 1 of relay A and, when armature r is in the working position, via working contact r to earth. After 160 ms, armature r assumes the working position for about 25 ms. The five-step character is converted into a seven-step character by means of an alphabet converter. A step is later added to the seven steps obtained in this way, so that each character sent consists of eight steps, which together take 8 X 20 = 160 ms. The relocation of armature r is caused by a distributor in the transmitter (not shown), which closes contact zk ^{1 for} approximately 25 ms with each rotation after 160 ms. This energizes relay R in the following circuit: - battery, contact zk ¹ , winding 1 of relay R, earth. This places anchor r on the normally open contact. When contact zk ^{1 is} opened, relay R is energized as follows: - Battery, winding 2 of relay R, earth. This puts armature r back on the normally closed contact.

In the working position of contact r , relay A 'is energized, as indicated above. Contact a ¹ is then closed. If contact r now returns to the rest position, relay A ' is kept energized by the following circuit: - Battery, winding 2 of relay A' , normally open contact α ¹ , normally closed contact r, earth. If relay A 'is energized, does contact a also go?

from the resting position to the working position. This does not cause any excitation as it does not close the circuit for relays. Contact J ¹ therefore remains in the rest position.

As a result, a flip-flop circuit designated SUB in FIG. 2 is supplied with a positive voltage. .

All i-contacts remain in the rest position. Since contact 0 ^{3 has also been} closed, relay ZP is energized and contact zp closes. If now contact zk ^{2 is} closed, the stepping magnet M ι is excited via normally closed contact s ¹ , whereby the punched tape of A is moved by one step. When converting the five-step alphabet into the seven-step alphabet, each character has been given an equal ratio of character and separator steps (three character steps and four separator steps). By adding a step with a positive polarity when sending a character from A , this ratio becomes four character steps into four separating steps.

A character from B is sent "the other way round", i.e. with three character steps and four separating steps.

Characters sent "in reverse" indicate that all steps of a character are sent with opposite polarity, for example: The character E is in the channels of subscribers ^ and B

O XXX OOO.

This character is sent unchanged by subscriber ^ "normal" in the common channel and by subscriber B as

X OOO XXX.

The additional step at B has negative polarity, so the final ratio is four separation steps to four character steps. This protects the identification step as well as the alphabet steps against incorrect transmission:

This is to be understood that the identification step and the alphabetic steps because of one the same ratio of character and separator steps spawns against incorrect transmission can be monitored. ,

The device according to the invention thus makes, inter alia, the transmission of confirmation of receipt and synchronization control characters, such as are used in a device known per se, superfluous. If A alone has to send a message, the contacts s ² to s ⁶ remain in the rest position, and the message from A goes through these contacts to an alphabet converter, which converts the five-step character into a seven-step character, with each character having the same ratio between . Drawing and separating steps is given (three drawing steps and four separating steps).

Now if B alone has a message to send, q ^{2 is} closed; q ¹ is now open. Re- 125 'lais B' is then over winding! and work

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contact r excites and is held via contact b ¹ and winding 2 in the same way as in the first case.

A difference compared to the first case is that when contact b ^{closes 2} relay 5 "is energized.

This has the consequence that contact s ¹ assumes the working position, as a result of which flip-flop SUB in FIG. 2 is now supplied with a negative voltage. Furthermore, the contacts s ² to s ⁶ also assume the working position, whereby the input of B is connected to the alphabet converter.

Contact s ⁷ is also put into the working position

been, whereby in the appropriate moments the stepping magnet M 2. promotes the tape from B by one step.

Incidentally, the broadcast proceeds in a very similar way to the first case. The third possibility is now considered, if A and B at the same time

ao send a message.

Both contacts q ¹ and q ² are then "closed, so that when the contact r is periodically switched over, the relays A and B 'are excited at the same time. The contacts a ¹ and b ¹ are then closed at the same time as a holding contact. The contacts a ² and b ² are turned over at the same time. Relay 5 * is only excited if d ² is now also in the working position.

Furthermore, a counting circuit consisting of relays C and D is activated.

This counting circuit ensures that a character from A and a character from B are sent alternately to the transmitter.

Sending a character from A takes 160 ms, then a character from B is sent, which also takes 160 ms (this gives half the telegraphing speed in relation to the case where either A or B alone sends messages).

The counting circuit causes, among other things, the actuation of contact d ² . This contact is now alternately 160 ms in the rest position (a character from A is then sent) and in the working position (a character from B is then sent). Relay 5 "ensures that toggle switch SUB in FIG. 2 is controlled alternately with a positive or negative voltage via contact s ¹ , namely with a positive voltage when a character is sent from A , and with a negative voltage, when a character from B is sent.

In Fig. 2 it is now shown schematically in which way the characters originating from subscriber A and subscriber B are characterized by different polarity.

Point ι (Fig. 2) is always on positive voltage. The seven steps from the alphabet converter (Fig. 1) are placed at points 2 to 8. The voltages shown graphically in FIG. 3 a are applied to points el τ to el 8.

Point eil z. B. receives a positive potential for 20 ms; then it is provided with a negative potential for 140 ms. ■

After the first 20 ms has elapsed, point el2 becomes positive for 20 ms and so on.

Points 9 to 16 are connected to a positive voltage source via resistors R 2 to Rg, among other things. These points ■ are connected to points el 1 to el 8 via blocking cells. Furthermore, points 9 to 16 are connected to points 1 to 8 via blocking cells and to a busbar Z via blocking cells, which leads to the input of the flip-flop circuit AT .

This busbar is provided with a negative voltage via a high-resistance R 1 (high-resistance with regard to the line resistance of a blocking cell).

If the positive voltage (from Fig. 3a) is now applied to point el 1 for 20 ms, point 9 becomes positive, since point 1 is also positive.

This positive voltage makes the rail Z at the outer end of the resistor R 1 positive via the blocking cell. A positive control voltage is thus applied to the input of the flip-flop AT. If the positive voltage is then applied to point el2 for 20 ms, point 10 becomes positive if point 2 is also positive (this is the case if there is a positive step at point 2).

The input of the toggle switch is now also controlled positively again.

If then the positive voltage is applied to point el 2 for 20 ms and at point 3 z. B. a separation step (with a negative voltage), point 11 is negative. The rail Z will then become negative under the influence of the negative voltage which is supplied via resistor R 1 , as a result of which the flip-flop AT is now controlled negatively.

If further in this way the points el ^. until el8 become positive in each case for 20 ms, the rail Z becomes positive if the one at the relevant points 2 to 8 is a drawing step, and negative if the one at the relevant points 2 to 8 is a separating step.

The toggle switch AT is controlled positively by the incoming character steps and negatively by the separating steps.

Points A and B of the flip-flop AT are connected to the anodes of the two tubes of this flip-flop.

If a character step arrives, the input of the toggle switch is positively controlled. Point A is then z. B. positive and point B negative. .

If a separation step arrives, the input of the flip-flop is controlled negatively; Point is then negative and point B positive. So if any telegraphic step arrives, it is found with the same polarity (normal) on the line connected to point A of flip-flop AT and with the opposite polarity (reversed) on the line connected to point B. Between points A and B of the multivibrator AT and the key device K, which down the transmitter, there are two blocking cell circuits Vi and V2.

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The circuit arrangement is chosen so that when a message originates from A (and is intended for C ), the message is sent normally. Point A of the toggle switch must then be connected to the key device K via the blocking cell circuit Vi (the connection between point B of the toggle switch AT and the key device K must then be blocked). If the message originates from B (and is intended for D. Ίο), the device operates in such a way that the message is sent in reverse. Then the connection between point B and the key device if must come about (the connection between point A and the key device must then be blocked).

The respective forward direction is brought about by the blocking cell circuits Vi and ^. These blocking cell circuits are controlled by the cooperation of a flip-flop SUB (FIG. 2) and a pulse flip-flop circuit P.

For clarification, it is shown in Fig. 3b how a pause character α arrives. This character is sent in the seven step alphabet as follows: separating step, character step, separating step, character step, separating step, character step, separating step.

An eighth step is added to each character. This is done by means of the voltages applied to points 1, el ι and 9. In interaction with the battery voltage supplied via R 2, these voltages always produce a positive control of the flip-flop AT in the period when the positive voltage occurs at point el 1. During this period, the output A of the flip-flop AT is positive and the output B is negative (see Fig. 3b).

The first step is always positive at output ^ of flip-flop AT and always negative at output B.

The further course of the lines given in FIG. 3 is self-explanatory. The first line shows the voltage that occurs at point A of flip-flop AT , while the second line shows the voltage at point B.

The trigger circuit SUB is controlled by the voltage supplied via contact s ¹ (FIG. 1). This voltage is positive when a sign emanates from A and negative when a sign emanates from B , as mentioned earlier.

If a character arrives from A , output A from flip-flop S UB ( hereinafter referred to as SUB-A ) z. B. positive and output B ( hereinafter referred to as SUB-B ) negative. If a character then arrives from B , SUB-A becomes negative and SUB-B becomes positive.

The voltages which occur at the points SUB-A and SUB-B are fed to the correspondingly marked points of the blocking cell circuits Vi and V2 .

The pulse flip-flop circuit P (Fig. 2) is now a pulse voltage, as indicated in Fig. 3c. The first line of Fig. 3c shows the pulse voltage as it occurs at point A of flip-flop P (point PA in the following). The second line of Fig. 3c shows the pulse voltage as it occurs at point B of the flip-flop circuit P (point PB in the following).

The voltages occurring at points PA and PB of the flip-flop circuit are now fed to the correspondingly marked points of the blocking cell circuits Vi and V2 .

The blocking cell circuits Vi and V2 are further provided with a positive voltage via resistors Rio and R12 and with a negative voltage via resistors Rn and R13.

The interaction of all the mentioned voltages then results that a character from A via barrier cell circuit Vi controls the device key K, and that a sign of B cells over circuit V2 controls the device key K. If z. B. first a character from A arrives, the trigger circuit SUB is controlled positive, SUB-A is positive and also the corresponding point 3 of the cell circuit Vi. If the positive pulse of the pulse flip-flop circuit P occurs, point PA of the blocking cell circuit Vi is also positive. Point 3 of the blocking cell circuit Vi is then positive.

The points SUB-B and PB of the blocking cell circuit Vi are then negative, so that point 4 is also negative.

In the blocking cell circuit Vi , a current then flows from point 3 to point 4 via the blocking cell circuit Vi, so that there is a conductive connection between points 1 and 2. Point SUB-A of the blocking cell circuit V2 is then positive, and point PB is negative when the pulse voltage occurs. Point 4 is then positive. Point SUB-B of the blocking cell circuit V2 is then negative and point PA is positive. Point 3 is then negative.

Under these circumstances, the blocking cell circuit V2 is blocked. As a result, device K is controlled by the voltage at output A (from AT and not by the voltage at output B) .

If the first step of the pause character α arrives from A (a separation step), it will again find a conductive connection between points 1 and 2 of the blocking line circuit Vi when the pulse voltage of the flip-flop P occurs , as can also be seen from the explanation given. A separation step goes as a separation step (normal) after the key device. The course of the sending of the pause character α is continued, as indicated in line 1 of FIG. 3 d.

If this is followed by a character from B , the ^: flip-flop SUB is controlled negatively. Output SUB-A becomes negative. The corresponding point of the cell circuit V2 also becomes negative. If the negative pulse of the flip-flop circuit P occurs, point PB of the blocking cell circuit V2 is also negative. Point 4 of the lock cell circuit V2 is then negative. The points SUB-B and PA of the blocking cell circuit V2 are then positive, so that point 3 is also positive.

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In the blocking cell circuit V2 , a current then runs from point 3 to point 4 over both sides of the blocking cell circuit Vz, so that a conductive connection exists between points 1 and 2. Point SUB-A of the blocking cell circuit Vi is then negative and point PA is positive when the pulse voltage occurs. Point 3 is then negative.
. Point SUB-B of the blocking cell circuit Vi is then positive and point PB is negative. This makes point 4 negative.

Under these circumstances, the blocking cell circuit Vi is blocked. As a result, K is controlled by the voltage at point B (of AT) rather than the voltage at point A.

If the first step of the pause character α (a separation step) arrives from B , it is passed on in reverse via output B of the flip-flop circuit AT , since when the pulse voltage of the flip-flop circuit P occurs, a conductive connection is established between points 1 and 2 of the blocking cell circuit V2 as can be seen from the explanation given. The separating step therefore goes as a drawing step (vice versa) after the key device. The course of the sending of the pause character α is then given further as on line 2 of FIG. 3 d.

The recipient

Fig. 4 gives the circuit diagram of the receiver. The received character controls the input flip-flop T. TLux Clarification is again based on the pause character α indicated in the description of the transmitter and shown in FIGS. 3b and 3d.

The first step of A is always a drawing step, the first step of B is always a separation step.

It is assumed that a drawing step at the output A of the flip-flop circuit G (hereinafter referred to as TA) produces a positive potential and a separation step produces a negative potential in TA . Furthermore, a sign from A in point TA appears normal, while a sign from B in point TA appears the other way round (it was sent the other way around).

A character from B then appears normally at output B of flip-flop G (hereinafter referred to as TB).

Relay OP (whose excitation winding in the anode circuit of a is received by the tubes of the flip-flop OR) ensure by means of contact, Op ¹ ensure that the busbar V upon receipt of a character from A Rühekontakt op ¹ with TA and upon receipt of a character of B over contact op ^{1 is} connected to TB .

In this way, the "inverted" characters from B are returned to their normal position in the receiver. So the characters from A and also the characters from B arrive normally on track V.

The switching of the contact op ¹ is accomplished by relay OP. The flip-flop circuit in which this relay is included is connected to TA via the blocking cell circuit a.

This lock cell maintenance provides a conductive connection between point TA and flip-flop OR in moments determined by the distributor.

The first step of a character from A, always a character step, sets relay OP to the rest position.

The first step of a character from B, always a separation step, puts OP in the working position.

So is alternately a sign of A TA via closed contact op ¹ to the busbar V and a sign of B of TB over contact also op ¹ to the busbar V. For accomplishment bringing the conductive connection between point TA and flop Oi? provides an electronic distributor EL (not shown). This electronic distributor contains eight times two tubes. In the anode circuits of the eight parts of the distributor voltages occur, as shown in Fig. 3a in the characters 1 to 8. .

These voltage surges are applied to the points marked with el ¹ to el ⁸ in Fig. 4. The points marked with + are connected to the anodes of the corresponding tubes, which are not in the time periods specified by the distributor in Fig. 3a ' are conductive, and the points marked with - are connected to the anodes of the corresponding other tubes.

At the moment when a negative potential occurs at points / 1 + (see FIG. 3 a), the blocking cell circuit α creates a conductive connection between point TA and flip-flop OR.

The toggle switch Oi? then sets the relay OP to the rest position when the first step from A occurs and to the working position when the first step from B occurs . Contact op ^{1 is} in the rest position when a character from A appears and in the working position when a character from B appears .

The first step of a character finds the blocking line circuit α conductive; the second step finds the blocking cell circuit b conductive. The second step, which is the first of the seven-step alphabet, controls the flip-flop circuit OA, and when a character step occurs, e.g. B. a positive potential and a negative potential when a separation step occurs.

The blocking cell circuit b becomes conductive when the positive potential occurs at point el 2+. This moment is determined by the distributor (see also Fig. 3a). The seven steps of a character or the blocking cell circuits b to h control the relevant flip-flops OA to OC one after the other, and the seven-step character -120 appears at the output of these flip-flops. It is then led, among other things, to an alphabet converter 7/5, which converts it into a five-step character, which then has to be sent to the relevant subscriber.

The output of the alphabet converter 7/5 is connected to the output trigger circuit UT. In the

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The polarized relays ET ι and ET 2 are added to the anode circles of the two tubes of this flip-flop. The tongues et ¹ and et ^{2 of} these relays key in cooperation with armature os of relay 05 "and, depending on its location, the printer device of subscriber D. Relay OS is located in the anode circuit of flip-flop OT. The character leaves the alphabet converter 7/5 with five group steps, which are a start-up step

ίο precedes and a lock step follows. The character comes z. B. from B and is intended for D. During the blocking step of the previous drawing, a positive voltage surge is applied to point E , after which point E becomes negative (due to the presence of blocking cell F , flip-flop OT does not respond to this negative voltage). As a result of the positive voltage surge supplied via blocking cell F and working contact op ² (relay Oi? Is in the working position due to the excitation in the first step of the character B), flip-flop OT is controlled, for example, in such a way that relay OS assumes the working position. Anchor os lies on the normally open contact, and point c is continuously connected to -battery during the following character from B. A character is passed on from B to D via contact et ² .

A drawing step takes place e.g. B tongue et ² in the drawn. Position, while a separation step takes tongue et ² in the working position.

When the following character originating from A arrives, armature op is placed on the normally closed contact, so that output C becomes free, as can be easily seen from the above and from FIG.

If only characters from A arrive, contact op ^{2 is} permanently in the rest position. Relay OS is then always energized in the same direction (it is in the rest position, as stated above). Contact os is then permanently in the rest position, so that output c is only encoded.

If only characters from B arrive, output d alone is continuously encoded.

Claims (3)

Patent claims: i. Radiotelegraph system, by means of which a two-channel connection partly via a single one common channel is maintained using a seven-step alphabet operating in the two-channel connection, in to which all signs for monitoring, an error-free transmission a fixed ratio between character and separator steps, indicated by automatic addition an eighth step (identification step) with a fixed polarity when posting each Sign and by the fact that this step keeps the same polarity from one channel and from other channel by automatically reversing the polarities of the character steps in the Posting in the common channel gets the opposite polarity and thus the steps of the characters of one of the two channels normal and the steps of the characters of ■ the other channel can be sent the other way around ', creating a fixed relationship between and separating steps of all characters of both channels are retained, the identifying step can be monitored against incorrect transmission at the same time as the character steps can. 2. Circuit arrangement for implementing the radiotelegraph system according to claim 1, characterized in that it has a blocking cell circuit for the identification step and the drawing steps, one of which (Fig. 2, 1) is permanently provided with a positive DC voltage at its input and the identification step causes, while the character steps of one and the other channel are successively applied to the inputs of the remaining lock cell circuits, and that these lock cell circuits (Fig. 2, 1 to 8) receive a voltage with the polarity of the seven character steps one after the other under the control of a distributor that this number of blocking cell circuits act on a flip-flop (AT) , _t with the said polarities appearing normal at the two outputs of the flip-flop (AT) , i.e. with the respective step polarity, and vice versa, i.e. with the respective opposite step polarity and depending on the channel affiliation about sper cell circuits (Fig. 2 ,, Vi and V 2) either normally or vice versa via the transmitter after the receipt of the common 'channel. 3. Circuit arrangement for implementing the radiotelegraph system according to claim 1 and 2, characterized in that it has a receiving flip-flop which is controlled by characters received via a common channel and at the two outputs of which the character appears normal and vice versa, that continues for the identification step and the drawing steps each have a blocking cell circuit (Fig. 4, o to h) , the first step using a relay with associated contact to determine whether a busbar (V) with the normal output or with the reverse output of the input toggle switch (T) is to be connected, the steps of the character via the blocking cell circuits (Fig. 4, b to K), which are made conductive one after the other, and via the flip-flops (Fig. 4, OA to OG) an alphabet converter (7/5 ) and control a key device (Pr) placed under the control of the relay controlled by the first step, by means of which the N message is routed to the correct channel. For this purpose 2 sheets of drawings © 509 630/68 1.56