CH350010A - Telegraph installation with plugged-in stations - Google Patents

Description

  

      The present invention relates to a telegraph installation with plugged-in stations making it possible, for example, to carry out a selection of stations and to carry out selective communication between a main station, such as a central or terminal station, and the various plugged-in stations, and quickly.



  This telegraph installation has a main station and a plurality of plugged-in stations and comprises an interconnection circuit between said main station and the plugged-in stations, each of the stations having transmission and reception equipment.



  According to the invention, this installation is characterized by means for transmitting respective characteristic invitation signals to invite said plugged-in stations to transmit messages to said main station, said invitation signals being transmitted according to a cycle in an order of predetermined succession, and by means at one of the stations for initiating an invitation cycle by transmitting an invitation signal assigned to one of said plugged-in stations, the last-indicated plugged-in station having means which selectively respond to the invitation signal assigned to it in order to automatically transmit to the circuit boarding circuit an invitation signal intended individually for a next connected station.



  The appended drawing represents, by way of example, an embodiment of the object of the invention. Fig. 1 schematically shows the various constituent elements of the installation. Figs. 2, 3, 4 and 5 together show a wiring diagram of one of the stations constituting this installation.



  Figs. 6 and 7 together show the additional circuits which should be provided in the event that a band transmitter is used to transmit teleprinter traffic in one of the pinned stations whose diagram is shown in FIGS. 2 to 5.



  Figs. 8, 9, 10, 11, 12, 13, 14, 15 and 16 collectively constitute a wiring diagram of the equipment and the connections constituting the main station, or terminal.



  Fig. 17 constitutes an assembly table of FIGS. 2 to 7.



  Fig. 18 similarly constitutes an assembly table of FIGS. 8 to 16. FIG. 1 therefore shows, in an extremely schematic manner, an installation of plugged-in stations in which an omnibus circuit L extends from a central or terminal station to a plurality of plugged-in stations of which only the first and the last have been represented. The terminal station comprises a reception distributor 20 intended to receive the keypad messages and also the teleprinter messages coming from the plugged-in stations, and a transmission distributor 22 intended to transmit the messages and the control signals to the plugged-in stations.

   The control equipment 23 is sensitive to the signals arriving via the line L and comprises means making it possible to distinguish between keypad traffic and fax traffic and making it possible to apply the keypad signals to a receiving appliance such as 'a data processing equipment, for example a computer 24, and to receive indicative signals therefrom with a view to their retransmission to a call keypad, and finally allows both to apply the signals constituting the teleprinter messages received to a teleprinter receiver 25. The terminal station also includes a band transmitter 26.

   The particular nature of the data processing equipment installed at the central station and which is sensitive to keypad signals, or the purpose for which it is used, does not in itself constitute a part of the present invention; such equipment can, for example, include equipment making it possible to store magnetically or otherwise signals representing an active inventory concerning stocks of goods, it can include accounting machines and punched cards, systems for reserving places on air or rail networks, and other known equipment.



  Each station of the system comprises receiver and transmitter distributors 20 'and 22', a control unit 28 and a keyboard 27 for handling keyboard traffic. Although it is possible to envisage the use of several keyboards which can be connected in turn using an assignor switch in the known manner, only a single keyboard has been shown, for the sake of simplicity. by station. A 25 'printer receives teleprinter messages that come to the station.

   It is advantageous to also provide a tape transmitter 26 'intended to transmit the teleprinter traffic to the central station, and in this case the printer 25' will also print the messages to be sent. <I> General description of operation </I> By pressing a request button in any of the plugged-in stations, the operator of this station records the fact that there is traffic (either keyboard or teleprinter) at this station pending transmission to the main station.

   If line L is unoccupied, pushing the button also sends a 25 millisecond open signal on the line, which results in the central station being aware that any station has traffic to pass. Due to the fact that the near simultaneous transmission of several open signals could cause a teleprinter character to appear on the line, stations are prohibited from reading any character for about 0.5 seconds after the acknowledgment of receipt of the open. The open also causes a lockout at all stations, which prevents an open from reaching the line when more than one demand button is pressed.

   After a waiting period of about one second intended to allow the reading circuits of the stations to come into activity, one of the stations, and preferably the main station as is the case in the example described here, automatically sends a particular character to invite the first plugged-in station that appears on the invitation series (this character will be assumed to be the letter B). Character reading circuits, such as groups of relays that are in stations, ensure that the first station is the only one that can respond to character B when it is used as a select character.



  If the first station has no traffic to transmit, it automatically transmits a special selection character to invite the station which comes second in the invitation series (we should put this character to be the letter C) in response to B. On the other hand, if the first station has keypad traffic to transmit, it transmits a particular functional character, such as the letter S, followed by keypad data. The S informs the central office that the information which follows it consists of keyboard data intended for the data processing equipment, for example for the computer represented. The S also disconnects all readers, so traffic characters will not be treated as signal characters.

   The message coming from the keyboard comprises a succession of characters stored on the keyboard contacts, which serve as a sort of buffer reserve, and each of said characters contains four coded telegraph message pulses, pulses in binary form which are in short binary figures known to specialists under the abbreviated name nation of bits. A fifth bit is advantageously added to each character in order to carry out a parity-odd check.

   The five bits of each character are sent serially over the line, combined with start and stop pulses to form telegraphic characters according to an arrhythmic permutation code. At the command center, or main station, a parity-odd check is performed on the characters received, and the four message bits of each character are sent to the computer or other data processing equipment in parallel form.



  At the end of an incoming keypad message, the data processing equipment immediately prepares a reply to be sent to the calling keypad station, and when the reply is ready the functional character S is automatically sent, followed by the reply. The response comprises one or more information characters each consisting of four bits which are converted into telegraph characters according to a code by start-stop permutation, as described above. The character S disconnects all the readers (which, in the meantime, had been switched on) and allows the code to be sent to the calling keypad.

   The parity of the characters is checked, and the four telegraphic bits of each character are injected at the input of the calling keypad and activate lamps or other signaling devices. There is no need to choose the appropriate keypad station when sending the answer, because the keypad of a calling station is set so that it accepts a reply only after it has sent a message itself. .



  If the first plugged-in station has teleprinter traffic to transmit, the space character is transmitted, followed by teleprinter traffic, this traffic being transmitted by means of a band transmitter existing at the station. The space character disconnects all the readers and lets the central station know that the information to be followed is to be sent to the receiving printer there. The fact that the calling station is transmitting causes the activation of the printer of this station. If the transmission is interrupted, for example due to the condition of the tape or for any other reason, it should be stopped long enough to allow the drives to be reset.

   When transmission has to resume, it is automatically preceded by a space which disconnects all readers. At the end of the message, the printer reads an end of message signal including a line, capital H, and closes a contact which disconnects the printer and the transmitter.



  If the transmitter is stopped for a predetermined time, for example 20 seconds, the printer and the transmitter are automatically disconnected. After the end of the message is read, the blank and line characters are passed through the transmitter. When a character other than these last two is on the perforated strip and comes on the probes of the transmitter, it stops the exploration of said strip, and it is only when the blank and line characters have become inactive again. that the request button will be able to perform the function for which it was set when it is pressed.



  At the end of either a teleprinter message or the keypad response, the main station automatically sends the selection character C to invite the second station on the invitation cycle. The second station reacts to character C in the same way that the first station reacted to character B except that, if it has no traffic, it automatically transmits another special selection character to invite the three. sth station.

   This process continues, with each station inviting the next if it has no traffic, and so on until the last station, and if the last station has no traffic either, it automatically sends a character. special says line feed.



  If no traffic has been received during an invitation cycle (inviting all stations, from the first to the last), said cycle is repeated. If no traffic has been received, a character (for example, the letter A) is emitted to remove the lockout, and this removal allows an open signal to reach the line if a request button is pressed.



  The invitation cycle can be programmed to invite loaded stations more frequently, since there is a switch for each station that allows invitations 0, 1, 2, 3, 4 or 5 times. If a station is put to sleep (invited 0 times) the main station automatically sends the invitation charac ter to the next station in the series when it receives the character corresponding to the dormant station. If it is, for example, the second station that is dormant and if the first station has no pending traffic, the main station receives B and sends C, and the main station receives C and sends the character of invitation intended for the third station.

   If a station is dormant and the preceding station has traffic, the main station will invite the station beyond the dormant station at the end of the message. If a station is allocated two or more successive messages and, therefore, it is invited more than once, it is invited 2, 3, 4 or 5 times (depending on the setting of the switch) in succession until 'to what an answer <: no be received. In such a case, the no response is sent when the station does not have to transmit the number of messages allocated to it, and at the end of its traffic it sends the invitation character to the next station.



       Since the power supply is not connected at the same time for all plugged-in stations, it is possible that a station tries to come online while a message is being transmitted. To prevent message traffic from acting like signaling characters, the station cannot respond to signals until the line is unoccupied for one second. To prevent the demand signal from interfering with traffic, the interlock is in action when the power is on. No station can send a request signal while the circuit is active, but the master station initiates an invitation cycle at defined time intervals, for example every ten minutes, if no request is received.

   Thus, the traffic coming from the first station will be collected ten minutes after the activation of the circuit.



  The main station can send teleprinter traffic only when the line is unoccupied or at the end of an invitation cycle. If * the circuit is unoccupied, a brief open is emitted to activate all the stations, then a transmitter period is provided. If the circuit is in action, the transmitter starts upon receipt of a non-response from the last station which, in this case, is a line feed character if the station has no message to transmit, or to the end of the indicator at the last station if it had keypad traffic, or even on receipt of an end of message signal in the case of teleprinter traffic coming from the station.

        The character required to select the desired station must be followed on the tape by a space character. The character selects the printer of the plugged-in station, and the space signal engages the printer and triggers the readers. If the transmission is stopped, it must remain stopped long enough to allow the readers to re-engage, and the transmission must be preceded by a space if it is to be resumed. If the transmission restarts without emitting a space, the printer is triggered, and it is also triggered if the transmitter does not restart within twenty seconds. When the printer receives the line signal (letter H), it is disconnected.

       <I> Detailed description </I> <I> circuits of plugged-in stations </I> Figs. 2 to 5 inclusive show the wiring of a plugged-in station essentially comprising the output part 27a of a keyboard (fig. 2), a transmission distributor 22 '(fig. 3), a receiving printer 25' (fig. 2). 4), and a receiving distributor 20 ', as well as the input part 27b of the keyboard (fig. 5). The brush holder arm 62 of the transmission distributor 22 'is rotated continuously at constant speed under the action of a motor (not shown) as long as the station is open for the transmission and reception of traffic.

   Normally, the distributor is put out of action, with respect to line L, by a circuit comprising a conductor 78, the switching arm and the contacts of row B of a rotary switch RS-1 (fig. . 2), conductors 79 and 80 (fig. 3) and closed contacts 3 of a K18 relay and conductor 77, so that the distributor will not be in the line circuit until the keypad is ready to send to line L.

   The arrythmic receiving distributor 20 'of FIG. 5, however, is normally in circuit with the paddle of an LR1 line receive relay.



  Figs. 6 and 7 show additional circuits which are necessary when using a band transmitter 26 'to transmit teleprinter traffic from the plugged-in station. The bars y1, y2 and y3 (fig. 3) are respectively inserted between the pairs of terminals 2 and 3, 4 and 5, and 6 and 7 when not using the tape transmitter;

   if we remove these bars and if we connect a row of terminals 1 to 18 of a visible cable at the bottom of the fia. 3 with a corresponding row of terminals corresponding to conductors, the wiring of fig. 6 and 7 have the effect of activating the band transmitter in the wiring of the plugged-in station.



  In the drawings, the various control, reading and coding relays are designated by the reference character K followed by a number, and it will be alluded to in the same way in the description which follows. <I> Functions of K12 </I> (fig. 4). - Due to the fact that a station may be connected during a command sequence, it should be prevented from responding to any signals before it is certain that the L line is unaffected.

   The starting electromagnet 40 (fig. 5) of the receiving distributor 20 'cannot be actuated by a spacing pulse from the line, until K12 is actuated by a tube with gas controlled by grid V7 (fig. 4), this tube advantageously being a thyratron. If the line L remains in manipulation, the grid of V7 is above the potential of the earth and it conducts after the heating time of the cathode (about ten seconds). If the line sends a gap, the grid of V7 is made negative by means of a circuit passing through the pallet of the line relay LR1, the solid ring 46 of the distributor 20 ', the conductor 47, the armature 5 and contact 4 of K12, and rectifier 49.

   When the line is going to manipulate, the grid of V7 tends to charge up to take a positive potential. If the heating time has expired, V7 conducts when its grid reaches the earth potential; if the heating time is not over, the poten tial of the grid continues to increase and V7 conducts when the heating time is over, which allows K12 to be activated by V7. When K12 operates, it earths through its contacts 3, which has the effect of short-circuiting V7, and K12 thus remains locked as long as the station is supplied with energy.

   The operation of K12 closes a circuit between the pallet of the receiving line relay LR1, the solid ring 46 of the receiving distributor 20 ', the conductor 47, the armature 5 and the contact 6 of the relay, the segments 42 of the distributor and the brush-holder arm 41 up to the operating winding of the starting electromagnet 40 to energize the latter and release the distributor brushes that a motor at constant speed sets in rotation by means of a clutch sliding in a known manner.



   <I> Character reading circuit. </I> - The starting pulse (spacing) of a received character activates the starting electromagnet 40 of the receiving distributor 20 ', forcing the brushes to make one revolution. The brushes pass over segment 1 during the first pulse of the character received, over segment 2 during the second pulse, etc. Segments 1-5 are each positioned relative to solid ring 46 such that the middle of a signal pulse is received by the segment. Segments 1 to 5 are respectively connected to the vacuum tubes V1 to V5 which control the character reader relays K20 and K24.

   If the first pulse of the received character is significant, V 1 conducts, and if it is a spacing V1 is non-conductive, and the tubes V2 to V5 operate in a corresponding manner. If V 1 is conducting, K20 is working. If the second pulse is significant, K21 operates; if the third pulse is significant, K22 is actuated; if the fourth pulse is significant, K23 is actuated, and if the fifth pulse is significant, K24 is actuated. For example, if the received character is Y, K20 and K24 are activated.



  When the brushes pass over segment 6 of the distributor, K11 (fig. 3) is actuated via the grid-controlled gas tube V6, such as a thyratron, the control circuit comprising the coil of K11, conductor 54, distributor segments 52 and 6, conductor 56, excited V6 tube, and ground armature 2 and K10 contact 1. K11 is characterized by slow reclosing due to the presence of resistor R5 which is mounted in parallel with its winding. The operation of K11 applies the potential of the earth from its armature 2 and contact 3 to conductor 55, armature 4 and contact 3 of K13 (fig. 4) and conductor 58 to explore the series. of contacts of K24, K23, K22, K21 and K20.



  If, for example, the character E (first significant impulse) is received, the earth impulse coming from K11 (exploratory impulse, or test impulse) travels from conductor 58, stepping through the reinforcements and the contacts of relays K24 to K21 de-energized and appears at contact T9 of K20 energized. If it is the blank character (all spacing pulses) which is received, the evaluating pulse appears at contact T7 of K20. If the command character S (first and third significant impulses) is received, the scanning impulse appears at contact B6 of K20.

   The invitation and selection characters cause the appearance of output powers on the terminals <I> t2 </I> and <I> t4 </I> groups of terminals t1 to t4 in circuit with the armatures and contacts from K20 to K24, according to the connections of the bars selectively inserted between these terminals. In this case, the bars y5, y6, y7 and y8 are connected to force the station to respond to its invitation character, which is supposed to correspond to the letter B.

       <I> Demand and lockout circuits. </I> - As already indicated above, if no traffic has been received by the central station during an invitation cycle, the control character A is then transmitted by the station control panel to remove the locking of the various plugged-in stations, which allows an open to pass on the line if a request button is operated in one of the stations.

   On receipt of character A (first and second significant pulses), a K10 lock relay (fig. 3) is actuated on a circuit comprising its right winding, conductor 57, contacts B8 of K20 energized (fig. 5) , contacts 1 of K16, contact T6 and armature 5 of K21 energized, and normally-open contacts T4, Tl and 4 of de-energized relays K22, K23 and K24, conductor 58, contact 3 and armature 4 of K13, conductor 55 and contact 3 and armature 2 of K11 earthed.

   The operation of K10 at its armature 2 removes the earth from the cathode of V6, which causes the extinction of this tube since its cathode is then connected to the positive battery through a resistor R7 which has approximately the same value as the resistor R6 which is in the tube plate circuit.



  When you want to send from the keypad, you press a request button 31 (fig. 3), which has the effect of applying the earth to a circuit comprising contacts 1 of K6 and the winding of K9, which causes K9 to work. This last relay blocks a circuit comprising its contacts 5 and the conductor 74 at the level G of the rotary switch RS-1 (fig. 2), and the setting of the switching points to earth. The earth coming from the contacts 7 of K9 activated is applied to a circuit comprising the contacts 9 of K10 activated and the coil of K18 which locks on the contact 7 of K9.

   Relay K18, at its contacts 3, opens conductors 80 and 77 and, consequently, line L, and, at its contacts 1, opens the circuit of K19 put into action. The latter relay has slow tripping characteristics due to the presence of resistor R9 connected in parallel with its winding. After about 25 milliseconds, K19 fires; at its contacts 1, it closes line L. The spacing signal passing on the line makes a cold cathode tube V10 conductive, and this causes the triggering of relay K10 due to the fact that the left winding of the relay is in opposition to the right winding.

   The spacing signal also rotates the brush holder arm of the receiving distributor 20 'by one turn.



  The opening of the line by two stations almost simultaneously can cause the appearance of a false character on the line. To prevent such a character from being read, K11 cannot work because the V6 tube is not conductive. The control circuit of K18 is interrupted at contacts 9 of K10.

   Triggering K10, with respect to its armature 2 and contact 1, again applies earth to the cathode of V6, and the grid of the tube rises exponentially. When its gate reaches the potential of the earth (about half a second after the triggering of K10), V6 conducts and K11 operates to generate, at its contacts 3, an exploratory pulse to read received characters.

       <I> Handling keyboard traffic. </I> - When its invitation character is received by the station, the explorer pulse appears on frame 2 of K9 (fig. 3), because the reading relays for characters K20, K23 and K24 have been energized in response to the reception of B by the line relay LR1. If the station does not wish to transmit (K9 not actuated), the scanning pulse on its armature 2 causes K6 to operate via a circuit comprising contact 1 of K9, the bar y1 and the coil of K6. By its contacts 4, K6 blocks in the direction of contacts B 1 of K7.

   An exploratory pulse coming from the ring 65 of the transmission distributor 22 'is transmitted on a circuit comprising the mature artery 2 and the contact T1 of K7, the contacts 6 of K6 and through the left winding of K8, causing the operation of the latter relay. At the end of the exploratory pulse, that is to say just at the moment when the brush of the distributor leaves segment 65, K8 is blocked by its contacts 5 and the left winding of K7, causing the operation of K7. When K8 was functioning, a path was closed by its contacts 5 towards one end of the left winding of K7, but K7 did not function during the duration of the scanning pulse since the earth was applied to both ends of its winding from the left.

   The operation of K7 at the level of its contacts B 1 triggers K6 and, at the level of its contacts B3, K7 opens the short circuit comprising the conductors 77 to 80 in parallel with the distributor to allow the sending of the invitation character. from the next station.



  Switches <B> IF, </B> S2, S3, S4 and S5 are used to formulate the character which will serve as the invitation character of the next station; those switches which are closed will cause the transmission of significant pulses and those which are open will generate spacing pulses transmitted by the distributor 22 '. If we assume that the invitation character of the next station is the letter C, the second, third and fourth pulses of which are significant, this means that switches S2, S3 and S4 will be closed, while switches S 1 and S5 will be open, with the result that the first pulse as well as the fifth pulse will exhibit the characteristics of a space.

   When the distributor brushes 22 'pass over the start segment S of the segmented ring 60, the line L is opened, sending the start pulse of the character. When the second, third and fourth pulses of the prompt character are significant, as in the present example, the line is closed passing through switches S2, S3, S4 and segments 2, 3 and 4 and the ring 61 of the distributor. The exploratory pulse generated by segment 65 during this turn of the distributor, passing through contacts T2 and T3 of K7 and the right-hand winding of K8, causes the tripping of K8 and, by means of the right-hand winding of K7, which is an assist winding, keeps K7 in action.

   At the end of the exploratory pulse from segment 65 of the dispenser, K7 is triggered. This relay is put into action and then triggered at the end of each exploratory pulse coming from the ring 65 in order to synchronize the breaking and establishment of the short-circuit established at the terminals of the distributor with the rotation of the distributor. The elements for storing and transmitting the keyboard signals are schematically represented in the transmitter part 27a of the keyboard (fig. 2).

    The various details of such a keyboard do not constitute part of the present invention, and various types of keyboards suitable for generating and transmitting signals to the central station are well known to those skilled in these matters, as well as those in which the signals are initiated by the set of pushbuttons or by a combination of pushbuttons and a coded selector plate as described in the EUA patent N 2564410.



  The signals are temporarily stored on contacts such as those indicated by groups 86, 87, 88 and 89 (fig. 2) or in any other # <memory,> from which the signal characters can then be transmitted to an output circuit.

   When the station invite character, such as character B, is received, the rotary switch RS-1 steps forward under the scanning pulse received from conductor 72 through armature 2 and contact 3 of K9 activated and bar y = at the first contact of row or level A of the rotary switch and through the switching arm of this level and the winding of the stepping electromagnet for move the switch forward one step. The rotary switch is of the type in which the switching arms are simultaneously advanced one step to the next contacts in their respective levels A to G at the end of the advance pulse.

   The second contact in the level B switch row that the switch has advanced to is keeping the transmit distributor 22 'shorted at this time.



  The transmit scan pulse from segment 65 of the transmission distributor on lead 82 and the level A switch row contact shorting wiring at point 2 advances RS-1 one step up to point 3 where the distributor stops shorting on level B.



  Earth applied to points 3 of level C and level E operates K1 and K3, which has the effect of connecting the first and third segments of the distributor ring 60 to the line. The rotation of the distributor while RS-1 is on point 3 transmits the character S (first and third significant pulses) which informs the central station that there is keyboard traffic to be sent.

   The explorer pulse from 65 and following the character S advances RS-1 one step to point 4 to send the first information character from the keypad, and this character is represented by the upper horizontal row of contacts 86 to 89 which are closed in permutation according to the recorded character to be transmitted. If the first, second, third or fourth pulses are to be significant, as determined by the selective closing of contacts 86 to 89 of the first row, K1, K2, K3 or K4 are put into action.



  In order to provide odd parity check, if a keyboard character has an even number of significant pulses, a circuit is closed by pulling line L through level B, point 4, of the rotary switch to armature 2 of K4, and through the contacts of K4, K3, K2 and K1 to armature 2 of K1, and on conductor 90 to segment 5 of distributor ring 60 to issue a fifth significant boost. If the number of significant pulses is odd, the circuit through K4, K3, K2 and K1 is not established and the fifth pulse is output as a gap.



       RS-1 is advanced by one step by the explorer pulse causing the transmission of characters which are sent to the keyboard and to the control relays K 1 to K4. When RS-1 advances one step to the point beyond the last character which, in the example chosen, is point 9, the distributor is shorted by conductor 78, the switch arm. and the short circuit wiring provided on level B of the rotary switch and leads 79, 80 and 77.

   For this position of RS-1, at level G, the holding earth of K9 is removed and K9 is triggered. RS-1 then advances itself step by step to point 1, passing through the remaining points through the short-circuit wiring placed on level A of the switch.

   It will be understood that, although the contacts 86 to 89 serving as signal memory only comprise five horizontal rows, and therefore five characters, in the keypad taken as an example, a much larger number will usually be transmitted, and in in this case, the additional elements of these memories, constituted by contacts or any other type of device capable of making it possible to store signals, are connected to additional points arranged in levels C, D, E and F of the rotary switch.

   It should also be understood that the wiring of the switching points will be multiplied in successive parts in the form of an arc of a circle of said levels so that the rotary switch always stops in the suitable position to start a new transmission cycle. characters from the keyboard.



  At the start of the keypad message, the functional character S is read at each station, causing an exploratory pulse on contact B6 of K20 and is applied to conductor 50 to activate K15 (fig. 4). At the end of the operating pulse, K15 is blocked by the winding of K13 and contacts 3 of K14 and contact 5 and armature 4 of K15, putting K13 into action. When K13 is running, the circuit leading to armature 5 of K24 is interrupted at contact 3 of K13, which prevents the message characters from being read as control characters.

   At the level of its armature and its contact 5, K13 passes the exploratory impulse to the conductor 83 and, from there, through the contacts 1 of K5 (fig. 4) and the conductor 67, to the parity-imparity control circuit. shown to the right of K20 to K24 (fig. 5) and to the right column of contacts from K20 to K23, but this does not affect the keyboard because, at this moment, it is not in operation. state to receive. At the level of its contact 3 and its armature 4, K15 in action removes the earth from K14, leaving K14 under the control of the conductor 43 and the contacts 44 (fig. 4) furnishing an earth, except when the distributor of reception 20 'is in its stop position.

   Under the effect of the continuous rotation of the distributor brushes, relay K14 does not trip because it is a slow trip relay. If the transmission is stopped, the distributor remains stopped and K14 trips. At its contacts 3, K14 opens the holding circuit of K13 and K15, allowing them to trip. With K13 triggered, control characters can be read.



   <I> Receipt of the response. </I> - The functional character S at the start of the response makes K15 and K13 work in the way described above. When the next character (which is the first significant character of the callsign) is received, the receiving exploratory pulse is connected by contact B10 and armature 9 of K20 if the first pulse is significant, it is that is, K20 is excited;

   the exploration pulse is connected by contact T8 and armature 7 of K21 if the second impulse is significant, by contact T8 and ar mature 7 of K22 if the third impulse is significant, and by contact 7 and reinforcement 6 of K23 if the fourth pulse is significant. The conductors 96, 97, 98 and 99 coming from the aforementioned reinforcements extend to the input 27b of the keyboard and, by means of decoding relays, the characters of the callsign cause the excitation of lamps or other signaling devices in the keypad in the known manner.



  K17 provides a means to control the parity-oddness of incoming characters. If an odd number of significant pulses is received, the scanning pulse from armature B2 of K20 and contact B 10 of the same relay causes a current to flow through the two windings of K17, and the flows generated by the two currents cancel each other out and K17 does not work.

   If an even number of significant pulses has been received, the receiving scanning pulse does not appear at armature B2 of K20 and current only flows through one of the windings of K17: this relay then operates. and is blocked by its switch contacts 6 and 8 and by the button 100 for triggering the alarm for error. The activation of K17 at its contacts 5 triggers an error alarm to announce that an error has been received. The alarm, which may include a buzzer or any other known signaling device, is triggered by pushing the trigger button 100. At the end of the response, K14 (fig. 4) is triggered, triggering K15 and K13.



   <I> Stop and start for maintenance. </I> - When it comes to transmitting information for maintenance purposes, the control character E is emitted to disable the read circuit. On reception of the E, the exploratory pulse appears at contact T9 of K20, activating K16 which blocks its contacts 10 to the earth. The opening of contacts 1, 3 and 5 of K16 prevents reading of any character other than the E stop for maintenance or restart after maintenance character (white). When the blank is received, the exploiting pulse coming from the contact T7 of K20 passing through the contacts 8 of K16 causes the triggering of K16.



   <I> Handling of printer traffic. </I> - If it is desired to transmit teleprinter traffic from the plugged-in station, the bars y1, y2 and y3 (fig. 3) are removed so that their respective pairs of terminals 2 and 3, 4 and 5, 6 and 7 are actively in circuit with the corre sponding conductors numbered 2 to 7. At the bottom right of fig. 3 are shown conductors 1 to 18 connected to a first row I of terminals, with like conductors connected to a second row II of terminals.



  When the corresponding terminals are connected by bars shown in broken lines, the conductors 1 to 18 lead to a ribbon transmitter circuit shown schematically in FIGS. 6 and 7, the ribbon transmitter being designated at 26 'at the bottom right of FIG. 7. This ribbon transmitter is associated with a ribbon arm <B> 101 </B> which, in the known manner, puts its contact to earth in the event of ribbon failure. The step by step advancement of the ribbon transmitter is controlled by the distributor 22 '(FIG. 4) as will be described later.

       <I> White time-out circuit <B> </B> and at the </I> <I> line. </I> - Considering the tape transmitter 26 '(fig. 7), if the character which is at this moment in the perforated band on the needles p of the tape transmitter is not white (any space) or at the line (all significant) one or more needles will contact the marking bus bar M and the remainder will contact the spacer bus bar S.

   Contacts 4 and 7 of K31, and contacts B5, B8 and T8 of K32 and conductor 101 connect all the needles together; therefore, with a character other than blank or line in the tape transmitter, the marking bus bar M is connected to the space bar S.

   So, with a character other than white or in the line, in the transmitter, the potential of the earth, through the armature 5 and the contact T4 of K26 (fig. 6), is applied to a circuit. comprising the conductor 102, the marking bus bar M (fig. 7), one or more needles of the sender, the spacing bus bar S, the conductor 104, the contacts B4 of K26 and the conductor 105 to actuate K33 (fig. . 7).

    If the character in the transmitter is white or on a line, K33 is not actuated, and the step-forward pulse from segment 64 of transmission distributor 22 (Fig. 3) is applied to one. circuit comprising conductors 9 and 9a (fig. 6), armature 6 and contact B5 of K26, conductor 106, contacts 1 of K33 (fig. 7), conductor 107, contacts 5 of K30 actuated and also the conductor 107a, by both the coils of K29 and the conductor 108 to actuate the electromagnet 114 for stepping the tape transmitter.

   When a non-blank or line character is advanced one step in the transmitter, the circuit offered for the passage of the one-step advance pulse is interrupted at contacts 1 of energized K33, preventing the transmitter to take a step forward.



   <I> Self-stop transmitter circuit. </I> - The current intended for the electromagnet 114 for advancing one step passes through the closing contacts before opening 4 and 5 of K29 and through a winding of K29 in parallel with the contacts 5 of K30 and the other bob swims from K29 with each step forward impulse. Since the fluxes generated by the currents in the two windings of K29 cancel each other out, K29 does not work.

   If the band arm 101 is lifted, as when the band does not have perforations, K30 is triggered and the current then flows through a coil only of K29, causing the operation of this relay, K29 blocks by its contacts 3, 5 and the one-step advancement electromagnet 114, now excited both K29 and the one-step advancement electromagnet. During the first advancement pulse of a step which follows, K30 restarts, K29 is triggered by an impulse of a step via the contacts 5 of K30. With K29 de-energized, the advancing electromagnet triggers at the end of the advancing impulse to advance the band transmitter by one step.



       Program <I> printer traffic. </I> - If blanks and line have been made inactive through the 26 'band transmitter and band arm 101 is lowered, pressing request button 116 on the transmitter (fig. 6) applies the earth potential, from the contacts 7 of K30 excited, to the conductor 110, the contacts 4 of K33 excited, the conductor 111, the contacts Tl of K32 de-energized, the conductor 112 and the button request 116 until the winding of K25, causing the operation of this last relay. At the height of its contacts 5, K25 is blocked by the conductor 112 so that the triggering of the button 116 does not trigger K25.

   The earth potential applied by contacts 8 of K25 to a circuit including conductor 1 causes K18 to function (fig. 3) if the locking is not in action, that is to say if K10 is actuated. When the invitation character B from the station is received, the earth potential on the y5 bar and the t4 terminal (fig. 5) is applied by means of the conductor 72, the armature 2 and the contact 1 of K9 , conductor 2, and armature 2 and contact 3 of K25 (fig. 6) to operate K26.

   If the keypad has a message, the earth does not reach conductor 2, but instead it passes through armature 2. and contact 3 of K9 which is then actuated, conductor 4 until contacts B1 of K26, conductor 5 and the stepping solenoid of rotary switch RS-1 (fig. 2) to actuate said switch. In this way, keyboard traffic is sent before printer traffic. If there is neither keyboard traffic nor printer traffic, the earth potential is applied to a circuit comprising armature 2 and contact 1 of K9, conductor 2, armature 2 and contact 1 of K25 and conductor 3 to operate K6 (fig. 3).

   The operation of K6 transmits the invitation character of the next station as described above.



  When K26 is operating, it locks to earth through its contact T6 and armature 5. With K26 activated, the earth is removed from conductor 102 and from the marking bus bar M, and the connection of conductors 104 and 105 is closed. found open, at contacts B4 of K26, from spacing bus bar S to K33. At the level of its contacts B10, the relay K26 keeps K25 blocked on the conductor 111, the contacts T1 of K32, and the conductor 112. At the level of its contacts B1, K26 opens the circuit going from the armature 2 and the contact 3 from K9 to the rotary switch RS-1 to prevent operation of RS-1 in the event that K9 is actuated during the scanning pulse of the invitation character.

    



  The exploratory transmission impulse, coming from segment 65 (fig. 3) of the transmission distributor 22 ', on the conductor 8, by the T10 con tacts of K26, the contacts 9 of K30, the conductor <B> 118, </B> contacts T3 of K32, conductor 16, contacts 1 of K13 (fig. 4), conductor 15, and contacts 2 of K28, cause K27 to function. At the end of the exploratory pulse, K27, at the level of its contacts 3, blocks in series with K28, and puts the conductor 119 to earth at the level of the contacts B3 of K32, which causes the operation of K28.

   If K30 were to trigger during the duration of the scanning pulse, this would have the consequence of causing the premature operation of K28 which, at the level of its contacts 3 and 4, would inadvertently remove the short-circuit of the distributor 22 '. In order to prevent this false maneuver, the exploratory impulse is applied to K27 (when K27 is actuated) directly by the armature 7 and the contact 6 of K28 and by the contacts 7 of K27. The earth at the level of the contacts 5 of K27 and on the conductor 17 makes K5 work (fig. 4) which is blocked by its contact 5 and its armature 4.

   The operation of K28 up to its contact 3 and its armature 4 interrupts the short-circuit comprising the conductors 6 and 7 in parallel with the distributor 22 '(fig. 3), and at the height of its armature 4 and its contact 5, K28 connects the line L, by means of the conductor 12, to the third segment 3 of the distributor ring 60. This rotation of the distributor emits the command character space (third significant pulse), which always precedes a printer message and which, as will be explained later, always precedes the resumption of an interrupted printer message.



  The exploratory impulse from segment 65 of the transmission distributor, at the end of the space character, passes over conductor 8 and through armature 7 and contact 8 of K2.8 and conductor 120, and puts in action K31. The stepping pulse coming from distributor segment 64 and passing through conductors 9 and 9b through contacts B1 of K32, conductor 122, contacts 6 of K25, conductor 123 and contacts 10 of K31, keeps K31 in action after the exploration pulse.

   After the forward pulse, K31 is blocked by K32 and conductor 125, contacts B9 of K26 and contacts 2 of K29 to earth, activating K32. The activation of K32 at the height of its contacts B3 triggers K27 and K28 and, at the height of its contacts Tl, K32 triggers K25. The line from conductor 7 is connected to the marking bus bar M through contacts T7 and armature 6 of K32, and conductor 102. The various transmitter needles p of the tape transmitter are connected to their respective distributor segments 1 to 5 of the ring 60 (fig. 3) on the conductors 10 to 14 through K31 and K32.

   If a pulse is marking, the line circuit is closed by the marking omni bus bar M, the transmitting needle, the distributor segment, the distributor brushes 62 and the common distributor ring 61 of the transmission distributor 22. The first message character is sent. The following forward pulse advances the tape transmitter by one step, passing through conductors 9 and 9a, armature B6 and contact B7 of K2.6, contacts T12 of K32 and both coils of K29.



  The space character is read by the station and operates K13 and K15 (fig. 4) in the manner described above; the operation of K13 prevents the message character from being read as a control character. With K5 in action, the receiving exploration pulse cannot actuate K17 (fig. 5), because circuit 67 is interrupted at contact points 1 of K5. The operation of K15 at its contacts 1 removes an existing holding earth on the conductor 84 coming from the printer 25. If the line L marks, a vacuum tube V9 is conductive, and if the line is on space, V9 does not drive. Thus, the message is copied by the teleprinter 25 '.

   If either of the relays K15 and K5 is inactive, the printer is constantly maintained in the marking position, whether the V9 tube is conductive or not.



  If the band arm 101 (fig. 7) is raised due to the absence of perforations on the band, the transmitter stops by itself; K30 is triggered and, at the level of its contacts 5, it makes K29 capable of entering into action during the next forward impulse. With K30 tripped and K29 in action, K31 and K32 trip. Triggering of K32 prevents the forward pulse from fallen K29 when K30 is reactivated. With K32 triggered, the line is again shorted through conductors 6 and 7 at contact T5 and armature T6 of K32.

   Due to the fact that the transmission is stopped, K13, K14 and K15 (fig. 4) are triggered and, at its contacts 1, K15 again applies a holding earth on a conductor 84 going to the printer 25 '. When the band arm 101 (fig. 7) has fallen, K30 comes into action, and with K30 in action and K13 (fig. 4) released, the exploratory impulse activates K27 and K28 as we have seen. described above. The entry into action of K28, which occurs at the end of the scanning pulse following the operation of K30, causes the automatic transmission of the space character before the resumption of transmission of the message characters by the tape transmitter.

   K31 and K32 operate as described above, except that K32 operates at the end of the scanning pulse because the circuit for the passage of the forward pulse is interrupted at contacts 6 of K25. The operation of K32 allows the forward impulse to trigger K29 and therefore to advance the band transmitter by one step; the transmitter is not allowed to restart until the tape lever 101 is lowered and the read circuit is restored.



  When the space character is read at the station, the scanning pulse applies the earth to the conductor 51 leading to the cathode of the V8 tube (fig. 4) and also to the trigger circuit of the tube from the conductor 66 and the contact. B4 of K20 (fig. 5). If the received character is not space, earth appears on the cathode but not on the trigger circuit of V8, which makes V8 conductive, and in this state V8 causes the triggering of K26 (fig. 6). With K5 triggered, printer 25 'is unable to respond to line signals.

   With K26 triggered, the tape transmitter 26 'is unable to start, because the activation circuit of K27 is cut at the level of the contacts T10 d <B> e </B> K26.



  When the transmitter has stopped by itself as stated above (K30 and K31 triggered), the earth potential coming from the armature T2 and from the contact T3 of K26 is applied to the conductor 126, at the contact 1 and armature 2 of K31, and conductor 125 to the cathode of a cold cathode tube V11 and to one side of its timing capacitor C10. A short circuit 128 at the terminals of capacitor C10 is eliminated at contact 3 and armature 2 of K31, and the capacitor is charged. If the strip transmitter has started, the timing capacitor is discharged through armature 2 and contact 3 of K31.

   If the transmitter has not started within a predetermined period of time, for example 20 seconds, the potential appearing on the capacitor reaches the trigger voltage of tube V11, which thus becomes conductive. The conduction of V 11, on the conductor 18, de-energizes K26 and K5 (fig. 4). K26, at the level of its contact T3 and its armature 2, removes the earth and short-circuits the capacitor at the level of contact Tl and armature 2 of the same K26. The station must then replace the tape containing the message, press the request button 116 on the transmitter, and wait for it to be prompted to transmit again.



  The end of message signal is the uppercase letter H. The reception of the capital letter H activates a contact 76 of the printer-pilot 25 '(fig. 4), and the closing of the contact causes the triggering of K5, and by the conductor 18 triggers K26 (fig. 6). By triggering, K5 applies the main earth to the printer-pilot. At the level of its contacts B9, K26 opens the holding circuit of K31 and K32 which are triggered. Triggering K32 prevents the probe pulse from advancing transmitter 26 'and bypasses distributor 22'.



   <I> Receipt of </I> printer traffic. - When there is printing traffic to be sent from the terminal station to one of the plugged-in stations, the reception of its printer selection character (by hypothesis the character G) determines the appearance of the scanning reception pulse at terminal t2 (fig. 5), and the earth potential at this terminal activates K5 via conductor 53, and K5 is blocked. The character then received is a space which activates K13 and K15, and once these relays are activated, the circuit can no longer read the message characters which will follow as control characters, and the printer 25 'responds to the signals of the line.

   With K5 actuated, the receiving exploratory pulse cannot actuate K17 (fig. 5) because the circuit passing through conductor 67 is then open at contacts 1 of K5.



  On receipt of the capital letter H, the printer 25 'is disconnected, as has been described above. If the transmission is stopped, its resumption must be preceded by the space signal, as described above. Receipt of a character other than a space after an interruption in transmission results in the printer being disconnected, as previously indicated. <I> Station operation </I> main. - Figs. 8 to 16 collectively constitute the representation of the wiring diagram of the existing switchgear at the main or terminal station.

   We see the line L in fig. 11, and in LR2 is shown a well-known line relay device in which, when transmitting from the terminal station towards the plugged-in stations, the outgoing signals sent on the transmit branch are applied to the top of the coils of the line relay, one of said coils being connected to an artificial line AL and the other to line L, so that the flows generated in these coils neutralize each other and the ar mature or pallet of the relay is not affected by outgoing signals.

   For incoming signals, the relay coils are in series and the relay paddle responds so that the pulse and gap pulses are applied to the receive branch.



       Circuit <I> reading characters. </I> - If K62 (fi-. <B> 11) </B> is actuated, the start pulse of a character received on line L operates the start electromagnet 150 (fig. 14) of the receiving distributor 20, forcing the brushes of the arm brush holder 151 to make a revolution, the circuit comprising the receiving branch (fig. 11), the armature 4 and the contact 5 of excited K22, the conductor 148, the rest segments 152 of the distributor 20 and the electro- starter magnet 150 to battery positive.

   Segments 1 to 5 of the distributor are connected to the vacuum tube circuits indicated by rectangle 156, these circuits being similar to those shown in FIG. 5 and described above and controlling the five relays for reading characters K55 to K59 of FIG. 14. The function of K62 will be explained in detail later.

   In the same way as that which was described above with regard to the plugged-in station, relay K55 of the character reading relay group (fig. 14) is activated if the first pulse is significant; K56 is activated if the second pulse is significant; K57 is activated if the third pulse is significant; K58 is activated if the fourth impulse is significant, and K59 is activated if the fifth impulse is significant. These relays are not actuated if their respective pulses are gaps. For example, if the Y character (first, third and fifth significant pulses) is received, K55, K57 and K59 are actuated.

   When the brushes are not felt on segments 6 and 154 of the distributor (fig. <B> 11), </B> K53 operates and applies an earth pulse which passes through its contacts 5, armature 4 and contact 3 of K45 and conductor 158 up to armature 2 of K59 (fig. 14) to explore through the contacts of K55 and K59.



  If it is the space character (third significant impulse) which is received, the earth impulse coming from K53 (exploratory impulse) appears at contact T3 of K55. If it is the character S (first and third significant impulses) which is received, the exploratory impulse appears at contact T5 of K55. If the Line Feed character (second significant impulse) is received, the exploratory impulse appears at contact T1 of K55. If it is the character E (first significant pulse) that is received, the scanning pulse appears at contact T8 of K55. If the blank character (all spacing pulses) is received, the exploratory pulse appears at contact T6 of K55.

   If a character other than space, S, A Feed, E and blank 'is received, the scanning pulse appears at K56 on contact T3. <I> Invitation of plugged-in stations to send. - </I> When the demand signal (open for 25 milliseconds) is received, the negative battery on the LR2 line relay gap contact (fia.

   11), passing through the reception branch, contacts 3 and 4 of K62 (which is de-energized at this time) and conductor 160 and the right-hand winding of K63, causes the activation of K63, which is blocked by its left winding and its contacts 7 on conductors 162a and 162 to earth on contact 6 and armature 7 of K74 (fig. 12). Activation of K63 starts the charge of the capacitor C20 in the trigger anode of a gas tube V24. After about a second, the voltage across the capacitor reaches the trigger potential of V24, which then becomes conductive and, in this state, this tube causes K62 to be activated.

   K62 blocks the conductor 164 to earth, which has the effect of switching off the tube V24. At the height of its armature 4 and its contact 5, K62 connects the pallet of the line relay LR2 to the conductor 148 and therefore to the starting electromagnet 150 of the receiving distributor 20.

      The exploratory pulse from segment 174 of the transmission distributor (fig. 9) is applied to a circuit comprising the conductor 176, the rear T4 and the contact 3 of K61 (fig. 8), the conductor 178, armature 4 and contact 3 of K74 (fig. 12), conductor 180, contact 1 of K66 (fig. 15), conductor 182, contacts 2 of K45 (fig. 11), conductor 184 , the contacts 9 of K63 excited, the contacts B7 of K62 excited, the conductor 186, the contacts 1 of K65 (fig. 15), the conductor 188 and the left winding of K75, which causes the activation of K75.

   At the end of the exploratory pulse, K75 is blocked by the left winding of K74 (fig. 12) to put the earth on contact 3 of K75, and actuates K74. The opening of contacts 6 and 7 of K74 allows K63 to trip because the potential of the earth is thus removed from the conductor. <I> 162a. </I> At the height of its contacts 1, K74 in action opens the short circuit which is normally at the terminals of the transmitter distributor 22, said short circuit comprising the conductors 192, 193 and 194. This rotation of the transmissions distributor emits the invitation character for the first plugged-in station.

   The first pad of the row of contacts constituting level D of the RS-3 rotary switch of fia. 9 and 10 is connected, by means of the conductor 195, to the battery if the first pulse of the invitation character is to be significant; level E plot 1 if the second pulse must be significant, level F plot 1 if the third pulse must be significant, etc. As the brush holder arm 172 of the distributor rotates, the line is closed through levels D to H of RS-3, the contacts of K61 (fia.

    8) and K73 (fia. 12), the segments of the distributor, the brushes, the common ring 171 of the distributor, the conductor 192, the contacts 4 of K76 (fi. 15), the conductor 206; contacts 4 of K66, and conductor 208 up to the transmission branch of line relay LR2 (fia. 11) if the line is significant (or marking). The fia. 9 schematically shows the switching levels or rows of RS-3s wired to emit character B (first and second significant pulses). It should be understood that the second pads of levels D, E, F, G and H are wired to emit the invitation character of the second station, the third pads that of the third station, etc.

      The exploratory pulse during this rotation of the distributor 22, passing through the armature 4 and the contacts T3 of K61, the conductor 178, the armature 4 and the contact 5 of K74 excited, the conductor 190, the contacts 5 of K75 and the right winding of K75, causes the triggering of this last relay and keeps K74 in action. At the end of the exploration pulse, K74 is triggered. K74 is actuated and then tripped at the end of the scanning pulse in order to synchronize the establishment and opening of the short-circuit at the terminals of the distributor 22 rotating freely with the rotation of the distributor.



  The invitation character is not perceived by the line relay LR2 because the receive branch is independent of the send branch. If the first station has no message to send, it transmits the invitation character of the next station as described previously.

   This prompting character is other than Spacing, S, Line Feed, E and White, and consequently the exploitative reception impulse appears at contact T3 of K56 (fia. 14), and the earth potential, by the intermediate of contacts 4 of K54, is applied to the conductor 196 and to the level C of the rotary switch RS-3 (fia. 10) to inform the terminal station that a character other than the five has been received. aforementioned characters.

   This exploratory pulse at the level C plot 1 of RS-3, through a conductor 19 8, a switch S2D and the conductor 200, actuates K81 (fia. 16) which blocks the conductor 202 on the break contact 20-4 of the rotary switch. RS-3. The potential of the earth, passing through contacts 3 of K81 on conductor 204 actuates RS-3, causing K81 to trip. When K81 triggers, RS-3 takes one step forward to pin 2.

       <I> Circuit </I> re-invitation. - Switches S1, S2, S3, S4 and S5 visible on the left of the fia. 10 include vertical columns of adjustable twin switches which serve to determine the number of times a station should be invited during an invite cycle. The system can handle many stations, but, as an example, the des sin represents only five switches for five stations (indicated by the numbers 1, 2, 3, 4 and 5) in the designations from SIA to S5D of the switches) since there are five vertical columns of these twin switches.

   The switches have an exclusion position C (zero times), and positions corresponding to 0 reinvitations (1 time), 1 reinvitation, 2 reinvitations, 3 reinvitations and 4 reinvitations, respectively. The twin switches as shown in the drawing are set to the 4 feedback position for all stations, but each paired switch is independently adjustable to any of the 0 to 4 feedback positions or exclusion position C.

   If station 1, 2, 3 or 4 is invited and all stations beyond it are excluded (or dormant), the exploratory impulse from a character other than space, S, Line Feed , E and White does not activate K81 (fig. 16) because path 200 is interrupted at S2D, S3D, S4D or S5D (fig. 10). If all stations are on, any character other than the above five characters cannot operate K81 while the RS-3 rotary switch is on pin 5.

   Since the character other than the aforementioned five characters cannot operate K81, it means that the station is the last station in the invitation series and there is only Line Feed which is accepted as a response no message. . On reception of the Line Feed, the scanning pulse coming from contact T1 of K55 (fia. 14) and passing through contacts 8 of K94 activates K81 on conductor 209.



  When K74 (fia. 12) is actuated during the invitation character, the earth, by its frame 7 and its contact 8, the conductor 210, the frame 6 and the contact 5 of K64 (fia. 15), the conductor 212, contacts 2 of K79, conductor 214, and contacts 1 of K85 (fia. 16), activates K80 which is blocked by contacts 1 of K85, conductor 214, contacts 2 of K79, conductor 214a , contacts 7 of K80, conductors 216 and 164, and contacts 2 of K64 to earth. The entry into action of K80 (fia. 16), at its contacts 3, starts the charge of capacitor C22, located in the circuit for tripping a tube V26 in a gas atmosphere. The operation of K81, at its contacts 7, applies earth to the capacitor to reset the time delay.

   Reception of a message triggers K80 which re-engages the timer as will be described later. In this way, the condenser continues to charge only if the no message response is not received. When V26 drives, it activates K82 and, at the height of its armature and its contact 3, K82 activates the rotary switch RS-3 on conductor 204.

   The earth, from the interlocking contact 205 of RS-3, on the conductor 207, passing through the contacts 5 of K82 (fig. 16), activates K85 which is blocked by its contacts 4 and the conductors. <B> 218 </B> and 220 up to contact 1 and armature 2 of K75. Running K85 triggers K80 which turns off the V26 tube, allowing K82 to trigger. Triggering K82 allows the RS-3 rotary switch to advance to the next pad. Earth, through armature 2 and contact 1 of K82 and contacts 6 of K85 and conductors 222 and 224, activates K63 (fig. 11).

    The operation of K63 initiates the transmission of the next invitation character, which is to be transmitted as described above.



  The reception of a keypad message or a printer message is described below.



  At the end of a response message obtained from the computer or other data processing equipment at the terminal station, or at the end of a printer message received from a plugged-in station, K78 is actuated, in a manner which is described below. At its contacts 5, K78 applies earth to conductor 224 and actuates K63 (fig. 11) to initiate transmission of the following invitation character. K78 also, at the height of its armature 2 and its contact 3, applies the earth potential to conductor 232, through armatures 2 and con- tacts 1 of K72, K71, K70, K69 and K68 (fi g. 9 ), and activate K67.

   When K78 trips, K67 is blocked in series with K72, through the close contacts before opening 10 and 11 from K71 to K68, the contacts 3 of K67, and the conductor 202 and the cut-off contact 203 of RS- 3 to earth by causing K72 to activate.



  If the message comes from station n and if this station is only to be invited once during each invitation cycle, the earth potential from armature 7 and contact 8 of K72 is applied to position 0 of one of the switches SIA to S5A corresponding to station n, passing through the arm of the switch and one of the level B contacts of RS-3 and through the advancement winding of 'a step from RS-3 to the battery, to activate RS-3. The opening of the breaker contact 203 of RS-3 triggers K67 and K72 and the triggering of the latter moves RS-3 to the next pad.

   If the station is to be invited more than once during an invitation cycle, after the next return response K78 (fig. 13) works again and K71 is put into action and, up to its frame 7 and of its contact 8, applies the potential of the earth to the contact of position 1 of the switches SIA to S5A, while K72 trips when K78 trips. Thus, if the station is to be invited twice, RS-3 is operated by frame 7 and contact 8 of K71. RS-3, when operating, triggers K67 and K71.

   If the station is to be actuated more than twice, the next time K78 kicks in, K70 is activated while K71 trips at the same time as K78 trips. Similarly, the station can be invited up to five times in succession, and this is determined by the setting of switches SIA to S5A.



  When a no-message response is received (this being indicated by a character other than Space, S, Line Feed, E, and Blank) and when RS-3 has advanced to a stud that is dormant, the potential to earth is applied by RS-3, level A, the dormant position C level of the rows of switches SIC to S5C of manually adjustable switches, on conductor 234, contacts 5 of K89 (fi, - ,.

   16) actuated, the conductor 236, the rectifier 238 (fig. 13), the conductor 224 and the left winding of K63 (fi-, 11), and activates K63 to initiate the transmission of the next invitation character of the manner which has already been described above. So if you invite a station that has been put to sleep, the next station in the invitation series is invited without having to wait for the V26 tube (Fig. 16) to be primed.

   K65 (fig. 15) is actuated on conductor 240 and one of switches SlB to S5B and level A of RS-3. The entry into action of K65 at its contacts 1, prevents the operation of K75 until RS-3 has advanced one step from the pad corresponding to the station put to sleep. K65 is activated whenever RS-3 arrives at a dormant station to prevent the character from leaving until RS-3 steps forward on its own from that stud.



  When a message is received by the terminal station, K84 (fig. 13) is activated in the following way: when RS-3 advances one step to the pad (6) beyond that corresponding to the last station, the earth potential from this pad on level A of RS-3 is applied to conductor 242, through armature 2 and contact 3 and the left winding of K84 (fig. 13), and operate K83. At the height of its armature 4 and its contact 3, K83 opens the holding circuit of K84, but it remains blocked through K83.

   The earth potential applied across armature 5 and contact 6 of K84 and ar mature 4 and contact 5 of K83 actuates K65 (fig. 15) on conductor 240, which prevents the following character from being issued. The potential to earth from the opening contact 203 of RS-3, on the conductor 242 and the contacts 9 of K83 and the conductor 244 and level B of RS-3, by itself advances RS- 3 with one step.

   When RS-3 advances one step by shooting from the stud, K84 is triggered, and the potential of the earth from its armature 5 and from its contact 4, and through the contacts 13 of K83 and the conductor 224, activates K63 (fig. 11). RS-3 advances by itself step by step to pin 1 through the shunted contacts on level B of the switch. The shunted contacts on level A keep K65 (fig. 15) actuated on conductor 240. When RS-3 reaches pin 1, K65 is triggered and the character used to invite the first station is transmitted.

   When K75 operates, earth is removed from conductor 220, and K83 trips.



  If no messages have been received during the invitation cycle, K84 (fig. 13) is not activated. When RS-3 advances to the pad located beyond that corresponding to the last station, the potential of the earth coming from this pad on RS-3, level A, through conductor 242, the ar mature 2 and contact 1 of K84 and conductor 246, activates K64 (fig:

      15) .At its contacts 2, K64 in. action triggers K62 (fig. 11). The exploratory pulse from segment 174 of transmission distributor 22, on conductor 176, armature 4 and contact T3 of K61, conductor 178, armature 3 and contact 4 of K74, conductor 180, contacts 1 of K66 (fig. 15), conductor 182, contacts 2 of K45 (fig. 11), conductor 184, contacts 9 of K64 (fig. 15) and conductor 188, activates K75.

   At the end of the exploratory impulse, K75 is blocked through the right winding of K74 (fig. 12), puts so much into action K74. The earth potential, applied from armature 7 of contact 8 of K74, through conductor 210 and contacts 7 of K64, and conductors 248 and 204, activates RS-3. Levels D, E, F, G and H <B> (fi-. </B> 9) of the rotary switch are wired in such a way that, during this turn of distributor 22, it emits the character A to suppress the deactivation (or lock-in) of the plugged-in stations.

   The end of the scanning pulse that follows character A allows K74 (fig. 12) to be triggered. Triggering K74 allows RS-3 to take one step forward, triggering K64 song (fig. 15). RS-3 then advances by itself step by step to pin 1.



   <I> Receiving keyboard traffic. </I> - If a station has keypad traffic to send, it transmits the character S in response to its invitation, as described above. When the S is read by the character reader relays K55 to K59 (fig. 14), the receiving exploratory pulse coming from the earth at the level of the contacts of K53 and passing on the conductor 158 appears at contact T5 of K55 for put into action K47 (fig. 11).

   At the end of the pulse, K47 is blocked through K45, contacts 3 of K46 and contact 3 and armature 2 of K47 to activate K45. When K45 is operating, the circuit leading to armature 2 of K59 (fig. 14) is interrupted at contact 3 and armature 4 of K45 (fig. 11), which has the effect of prevent message characters from being read as control characters.

   K45 at the height of its armature 4 and its contact 5, by conductor 267, armature 5 and contact T4 of K48 (fig. 14), does not apply the exploratory impulse to the mismatch control circuit. K55 and K59 character reading relays and to the closing contacts B10 and B8 of the character reading relays. The associated reinforcements are connected to the input conductors 250 to 253 of the computer or other data processing equipment.

   At the height of its contact 1 and its armature 2, K47 removes the earth from K46 under the control of a contact 260 controlled by a cam (fig. 11) which earths except when the receiving distributor 20 is in the position. stop. When continuously rotating the distributor, K46 does not trip because it is a slow trip relay. The potential of the earth coming from the armature 8 and the contact 9 of K47 activates K79 (fig. 13) on the conductor 262.



  K79 is blocked by its contacts 7, K83, contacts 1 and conductor 162 to contact 6 and to the earth armature 7 of K74 (fig. 12). K79, at. height of its contacts 2, opens the main circuit on conductor 214 and contacts 1 of K85 (fig. 16) for K80, triggering K80. K79, at the height of its contacts 9, activates K84 which indicates that at least one plugged-in station has sent a message during the invitation cycle. The operation of K79 causes the start of the charging of the capacitor C24 of the starting circuit of the gas tube V25.

   When the response is complete, the next character is emitted. K79 is triggered when K74 kicks in. If the response is not sent, K79 is not triggered and the V25 tube lights up and sets an alarm signal meaning that the response is late.



  When the first character of the message is received, the scanning reception pulse coming from segments 154 and 6 of distributor 20 (fig. 11) causes K53 to be activated and, at its contacts 5, the relay applies a exploratory impulse through armature 4 and contact 5 of K45. If the first pulse is significant, it is applied through B10 of K55 (fig. 14).

   If the second pulse is significant, it is applied through B 10 of K56. If the third pulse is significant, it is applied through B8 of K57. If the fourth pulse is significant, it is applied through B8 of K58.

   Significant pulses apply earth to conductors 250, <B> 251, </B> 252 and 253 and at levels E, D, C and B of the rotary switch RS-2 (fig. 14), and, from there, into the computer. The exploratory impulse: coming from contacts 3 of K53 (fig. 11) and passing through contacts 10 of K45, contacts T2 of K48 (fig. 14) and armature 5 and contact 6 of K47, on the conductor 264, step forward RS-2. Significant pulses of the second character send a pulse through the second;

   RS-2 levels dishes. The following characters are distributed to the remaining RS-2 plots in an analogous manner.



  K60 (fig. 15) provides a means to control the parity-oddness of the characters that occur. If an odd number of significant pulses is received, the scanning pulse passing through conductor 268 to K59, armature 8, and K58, contact B8, causes a current to flow through their coils of K60, and as the flows generated by the two currents cancel each other out,

   K60 does not come into action. If an even number of significant pulses is received, the receiving scanning pulse does not appear at armature 8 of K59, and current only flows through a single coil of K60, putting K60 in action. The control circuits are interrupted at the height of contact 1 of K60 and contacts 6, 7 of K60, the relay being blocked by its armature 5 and its contact 7 and the push-button 270. An error alarm is thus set. action by K60.

   Activation of push-button 270 triggers K60.



  At the end of the incoming keypad message, the distributor 20 stops, which allows K46 to trip because the contacts 260 (controlled by cams) of the distributor are open, these contacts being closed continuously except when the distributor is in the off position. The triggering of K46 triggers the triggering of K45 and K47.

   The potential of the earth coming from the shunted pads of level A of RS-2 and passing through the spring-switch 272, the conductor 274, the contacts 4 and 5 of K47, the conductor 264 and the coil of RS-2, moves the switch by itself step by step to pin 1.



  When the response is ready, the exploratory transmission pulse coming from segment 174 of distributor 22 (fig. 9) passing through contacts T3 and 4 of K61, contacts 292 associated with pin 1 of level B of rotary switch RS -1 (fig. 8), conductor 230, contacts 9 and 10 of K61 and conductor 231, activates K73 (fig. 12).

   At the end of the exploratory impulse, K73 is blocked through its contacts 5, the conductor 233, the right-hand bobbin of K61, the conductor 230 and contact 1 and armature 2 of K78, putting K61 into action . K61, at the level of its contacts T2, opens the short-circuit comprising the conductors 193-194 placed in parallel with the distributor 22. The operation of K61 and K73 (fig. 12) respectively connects segments 1, 2, 3 and 4 from the distributor to the right-hand interlocking contacts of K41, K42, K43 and K44 (fig. 8).

   Earth coming from pin 1, levels G and E, of RS-1 activates K41 and K43. With K41 and K43 in action, this turn of distributor 22 emits the character S (first and third significant pulses). The exploratory pulse passing through K61, contacts T4 and 5, advances RS-1, one step, to pin 2 at the end of character S.

   While RS-1 is on pin 2, the first character of information from the response is sent. If the first, second, third or fourth pulses are to be significant, K41, K42, K43 or K44 are put into action.



  To carry out a parity-imparity check, and if the number of pulses to be transmitted is even, a circuit is closed from the fifth segment 5 of the ring <B> 170, </B> through the .coi B4 and 5 of K61, the RS-1 level C switch pin 2, up to K44, armature 2, through the left contacts of K44, K43, K42 and K41 up to to the mature ar 2 of K41 and, from there, to conductor 195,

    to emit a fifth significant pulse. If the number of significant pulses is uneven, the circuit through the left contacts of K44 to K41 is not offered and the fifth pulse is output as a gap.



       RS-1 is advanced step by step by the operating pulse emitting characters which are produced by the response of the computer and the controller relays K41 to K44.

   When RS-1 is on a 241 pad corresponding to the last character of the answer, the earth potential is applied from armature 2 and contact 1 of RS-1 passing through terminal 240, the 241 of level B of the switch, the conductor 230 ', the contacts T10 and 11 of K61, the left winding of K61 and the conductors 228 and 226, and actuates K78 (fig. 13).

   Activation of K78 removes the earth from its contacts 1 and triggers K73 (fig. 12), but K61 is kept in action by the exploratory pulse which passes through its left winding. The function of K78 has been described previously. At the end of the exploration pulse, K61 and K78 are triggered. When K61 trips, the valve short-circuited at contacts T2 of K61.

   Grounding through breakout contact 3 of RS-1, level A, and contacts B1 of K61, allows RS-1 to step forward on its own to pin 1.



   <I> Reception of printer traffic. </I> - If a plugged-in station has printer traffic to send, it sends the space character in response to its prompt. When space is read, the receiving operating pulse appears at contact T3 of K55 (fig. 14) to set. action K47 (fig. 11) and K48 (fig. 14).

   K45, K46 (fig. 11) and K79 (fig. 13) operate as described above - with regard to keyboard traffic. With K48 in action, the explorer pulse cannot advance RS-2 step by step (fig. 14) or go to the computer and to the parity check circuit, because the circuits are interrupted at the level of contacts T2 and T4 of K48.

       The exploratory pulse passing through armature T5 and contact 6 of K48, and reaching armature 5 of K59, appears at the height of contacts B8 of K55 if the character on the line <B>> </B> (Figure Shift) (first, second, fourth and fifth significant pulses) is received;

   at contact B 1 of K55 if it is the character H (third and fifth significant pulses) which is received, and at contact B3 of K55 if any character other than H is received.



  With K47 and K48 in action, the holding earth on conductor 277 and switch 276 is removed from printer 25 (Fig. 11). If the line -is prominent (or significant), the vacuum tube V21 is conductive, and if the line is spacing, the tube is not conducting. In this way, the message is copied by the receiving printer.

   If switch 276 is open and thus removes the printer's holding ground, the printer will act like a pilot device to copy all incoming traffic, whether it be keypad messages or tele-printer messages.



  If the transmission ceases, K45, K46 and K47 trip, and with K47 tripped the holding earth on lead 277 is again applied to the printer. If the transmission is resumed, it is preceded by space which again activates K45 and K47, and the printer obeys the signals of the line.

   When the transmission stops (K45 off and K48 on), earth is applied to the cathode of the cold cathode gas tube V22 (fig. 11) through contacts 6 and 7 of K45 and the con tacts B4 and 5 of K48.

   The capacitor C25 placed in the trigger circuit of V22 begins to charge because the short-circuit established at the terminals of the capacitor is eliminated at the level of contacts 7 and 8 of K45.

       After resuming transmission, earth is removed at contacts 6 and 7 of K45 and the capacitor discharges through contacts 7 and 8 of K45.

   If the capacitor has been allowed to charge up to the sudden ignition potential of V22, then this tube becomes conductive. The conduction of V22 sets in motion an alarm device meaning that the transmission has been stopped without there being any signal <end of message (at line and H).



  On printer traffic, the terminal station does not send a response, so that K61 (fig. 8) is not activated. Printer traffic always ends with a capital H.

   If the character on the line (Figure Shift) is received, the explora- tor pulse appears at contact B8 of K55 (fig. 14) and activates K49, and through contacts 3 of K49 apply the earth potential. at one end of the left winding of K50, which prevents K50 from coming into action for the duration of the scanning pulse.

   At the end of the exploration pulse, K49 is blocked through K50, contacts 1 and 2 of K51 and contacts B7 of K48, activating K50. When the character H is received, the exploratory impulse appears at contact B 1 of K55 (fig. 14) and through contacts 7 of K50 activates K51.

   Activation of K51 triggers K49, but the energizing current of K51 keeps K50 in action. At the end of the pulse K50 is triggered and K51 is blocked through its contacts 2 and 3 and contacts B7 of K48.

   If the character that sweats the line is not H, the exploratory impulse coming from contact B3 of K55, passing through contacts 5 of K50 and contacts 5 of K49 drops K49, which causes the tripping of K50.



  When K50 is operating, the earth coming from its contacts 3 and contacts 8 of K51 and conductor 226 activates K78 (fig. 13). K78 then operates as described above to see if the station should be invited back, the activation of K78 causing K63 to activate (fig. 11).

       After stopping transmission, K45 is triggered and the transmission explorer pulse activates K75 (fig. 15) and K74 (fig. 12) to send the next invitation character. The activation of K74 triggers K48 which triggers K51. When K51 was in action, the capacitor C26 placed in the snap circuit of the gas tube V23 (fig. 14) could be charged.

   If the transmission does not stop after reception of to the line H, that is to say if K51 remains in action, the tube V23 lights up. Ignition of the tube establishes an alarm signal which indicates that the end of message signal has been received but that the transmission has not ceased. <I> Transmission of printer traffic. </I> - The = printer traffic is transmitted from the terminal station by means of a well-known type of 26-band transmission distribution device (fig. 15),

   the transmitter contacts being connected to contacts 1 to 5 of the associated distributor. Such an apparatus will advantageously, although not absolutely necessary, be the Model 14 transmission distributor manufactured by the Teletype Corporation of Chicago, Illinois, or it may be a transmitter-distributor such as that described in the United States patent. NI, 1805374.

   The. Distributor contacts 6 are closed when the distributor is unoccupied and therefore keep line circuit 206, 208 closed at that time.

   The rotation of the distributor during the successive cycles is controlled by an electromagnet 297 constituting a clutch and which is connected, through the lower contacts of the belt tensioning arm 300, in series with the conductors 302, 303 of the starting circuit. . The step-by-step advancement of the band transmitter is effected or is controlled by a band provided on the distributor in known manner.



  In the arrangement shown, it is assumed that there will be a largely sufficient supply of tape, perforated so that the tape transmitter does not have to stop by itself before the message has been fully transmitted. However, in the event of a self-stop occurring during the transmission of a message, K91 would be triggered and earth would be removed from conductor 301.

    The tape can then be removed from the transmitter and reinserted, and after pressing the start button 308 again, the selection character of the plugged-in station followed by a space character will be retransmitted immediately before the information characters. contained in the message.

    If it is desired to have a continuous retransmission automatically after an auto-stop, a relay assembly similar to that employed at a plugged-in station, shown in figs. 6 and 7, can be provided to automatically cause the transmission of the space character D immediately before the resumption of the message.



  A printer pilot 306 is connected in series with the transmitter contacts, and the printer has a cam controlled contact 310, which closes when the end of message signal is transmitted by the tape transmitter and is received by the printer. -pilot, the end of message signal comprising the line, H,

   and usually being followed by line (Letter Shift).



  When there is a message to send, you press; on the start button 308 and, assuming that the contacts on the band arm are closed, earth from the top contacts of the band arm is applied through, the conductor 298 and the start button 308 for exci ter the right winding of K91; K91 is then actuated and is blocked through its contacts 1, so that the push-button 308 can be released.

    At the level of its contacts 3, the activation of K91 applies an earth to the conductor 301, this earth thus remaining applied until the end of message signal and causing the closing of the contacts 310 of the printer 306, from which it results that the circuit passing through contacts 2 of K91 and its left-hand winding releases the relay, and the earth is removed from conductor 301.

   Contacts. 2 of K91 prevent the relay from unexpectedly restarting in the event that printer contacts 310 remain closed for a period of time after the end of message or uppercase H signal has been received.



  If the line L of fig. 11 is unoccupied (K62 of fig. 11 disabled), the earth applied to conductor 301 (fig. 15), to contacts 4 of K64, to conductor 314, to contacts T4 of K62 (fig. 11) and to conductor 256, activates K66 (fig. 15), and K66 is blocked by its contacts 6 to conductor 301.

   Earth coming from conductor 301 through contacts 4 of K64, conductor 314, contacts T6 and 7 of K62 (fig. 11), rectifier 289 and conductor 290, actuates K76 (fig. 15) and, from contacts. T6 and 7 of K62, earth on conductor 287 and rectifier 288 activates K63.

   K63 tries to cause a prompt character to be issued, but the. circuit available to the path of the exploratory pulse from segment 174 of transmission distributor 22 (fig. 9) (on conductors 176, 178, 180) to actuate K75 (fig. 15)

   is interrupted at contact 1 of K66. The operation of K76 up to its contacts 4 opens the control circuit of K77.

   About 25 millseconds after the activation of K76, K77 trips at the end of this period of time as a result of the slow tripping characteristic conferred on it by the presence of a resistor 279 shunting its winding, which causes the close the send branch at K77 con tacts 1,

       which emits the 25 milliseconds open to lock (or sleep) all stations. Operation of K63 (fig. 11) initiates the gas tube timing circuit V24, and when the tube ignites, it activates K62.

   With K62 and K66 in action, the short-circuit across the terminals of the transmitter contacts is open at contacts B2 of K62,

       as well as contacts 4 of K66 to place the tape transmitter in the send branch. The transmitter control circuit is closed from conductor 302 passing through contacts 8 of K66 and conductor 304 and contacts B9 of K62 (fig. 11) to conductor 303.



  If the invitation cycle is in progress (K62 in action), the band transmitter can only be switched on: at the end of an invitation cycle. If the invitation cycle does not have to be repeated (K64 in action), K66 and K76 are activated as described above when K62 and K64 are activated.

   If the cycle has to be repeated, K83 (fig. 12) is activated. Earth coming from conductors 301 and 314 passing through armature 7 and contact T8 of K62, conductor 258, contacts 7 of K83 (fig. 13), and conductor 256, actuates K66 (fig. 15) .

   When K66 and K62 are actuated, the transmitter contacts are in the transmit branch and the control circuit is closed as described above.



  At the end of the message, a fine signal from mes sage, that is to say a capital letter H, acts so that the contacts 310 of the printer 306 (fig. 15) close and complete a circuit passing through the winding. left die K91, which triggers the relay which, at the level of its contacts 3,

         then eliminates the earth of the conductor 301 which opens the maintenance circuit of K66: K66, at the height of its contacts 4, allows the exploratory pulse to actuate K75 to emit the first invitation eazactère. K66 is a slow tripping relay,

         in order to give the reader time to return to the circuit at all the stations.



   <I> Automatic cycle execution circuit. </I> - The repeat cycle timer 280 (fig. 11) comprises two cams driven by a motor, these two cams being oriented with respect to each other on a common shaft so that each cam actuates switches once every ten minutes. The cams are set so that a switch 282 closes 9,

  5 minutes after the other switch 281. When the switch 281 closes, the earth passing through the contacts T1 of K62, the conductor 284, and the contacts 1 of K63, activates K52 which is blocked by its contacts 5 and the contacts. Tl of K62. If there is any traffic, K62- is activated and K52 is not when the switch closes.

   When the other switch 282 closes, earth passing through the switch and through contacts 3 of K52, conductor 287 and rectifier 288, operates K63, and through conductor 29.0 operates K76 (fig. 15). K76 determines the emission of a.

         open for 25 milliseconds which has the effect of causing the locking (or putting to sleep) of all the plugged-in stations, and K63 initiates the invitation cycle.

   If K62 is actuated (invitation received) between the time the first switch 281 is closed and the time the second switch 282 is closed, K52 is tripped and K63 and K76 are not actuated.

 

Claims (1)

CLAIM Telegraph installation with plugged-in stations having a main station and a plurality of plugged-in stations and comprising an interconnection circuit between said main station and the plugged-in stations, each of the stations having the transmission and reception equipment, this installation being characterized by means making it possible to transmit respective characteristic invitation signals for inviting said plugged-in stations to transmit messages to said main station, said invitation signals being transmitted according to a cycle in a successive order. predetermined, and by means at one of the stations for initiating an invitation cycle by transmitting an invitation signal assigned to one of said connected stations, the last indicated connected station having means which selectively respond to the invitation signal assigned to it to automatically transmit to the circuit boarding circuit an invitation signal intended individually for a next connected station. SUB-CLAIMS 1. Installation according to claim, characterized in that each plugged-in station has means for transmitting said invitation signal to a following station in the form of a telegraphic signal by permutation each time a plugged-in station receiving its signal. own invitation signal of a previous station is not able to transmit messages. 2. Installation according to claim and sub-claim 1, characterized in that all the plugged-in stations are established so as to successively receive their characteristic invitation signal during said cycle, and this until the cycle invitation has been completed. 3. Installation according to claim, characterized by switching means for selectively putting to sleep one or more of the plugged-in stations and means at the main station which come into action when a plugged-in station transmits the characteristic invitation signal. for another plugged-in station which is put in som meil, so that the characteristic invitation signal intended for the next non-dormant station in the series of said plugged-in stations is automatically transmitted. 4. Installation according to claim, characterized by switching means for allowing some of said plugged-in stations to effect one or more separate message transmissions during an invitation cycle. 5. Installation according to claim, characterized in that the last plugged-in station forming part of the invitation cycle has means which respond to its characteristic invitation signal and cause the transmission of a predetermined past signal. on the plug-in circuit in the event that said last station has no message transmission traffic, and that the main station has means for acknowledging receipt of said predetermined signal by indicating to the equipment installed at the main station that the invitation cycle has been completed. 6. Installation according to claim, characterized in that each plugged-in station has means making it possible to store a traffic transmission request signal and a read circuit to respond selectively to reception of its particular invitation signal, said stored request signal and said particular invitation signal coacting to apply to the plugging-in circuit a locking or dormant signal, and that means at the other plugged-in stations spreading said locking signal to silence said other stations their respective read circuits to prevent them from reading the message traffic passing between the plugged-in station which made the request and the main station. 7. Installation according to claim and sub-claim 6, characterized in that the main station has means which come into action after a traffic transmission has been received from any of the plugged-in stations during the course of the cycle invitation, to immediately start the continuation of the invitation cycle. 8. Installation according to claim and sub-claims 6 and 7, characterized in that the main station comprises means responding to the end of the message traffic between it and the plugged-in station which had requested to transmit during an invitation cycle. , said means ensuring the transmission of the characteristic invitation signal attributed to the next plugged-in station in the series of invitations. 9. Installation according to claim and sub-claim 4, characterized in that each plugged-in station has means responding to its invitation signal and means which come into action either when there is no traffic, or in the case where the number of separate message transmissions it had sent is less than the total number allocated to it, so that the invitation signal allocated to the next plugged-in station in the plug-in circuit is automatically transmitted to the plug-in circuit. series, said next plugged-in station and the remaining plugged-in stations in the series each having means responding to its particular invitation signal received from a previous plugged-in station in the series for transmitting the particular invitation signal from the next plugged-in station when any such station has no message traffic or when it transmits less than the number of separate message transmissions which has been allocated to it, until the invitation cycle is terminated. 10. Installation according to Claim, characterized in that the equipment for transmitting and receiving messages from the plugged-in stations comprise a keyboard and memory-type means serving to produce and temporarily store a series of coded telegraph characters or signals representing a keyboard message, and they also include distributing means for effecting the transmission of telegraphic signals according to a permutation code representing said characters, the receiving equipment at the main station comprising means suitable for receiving the keyboard message coming from the invited plugged-in station and also means responsive to said message for transmitting back to said invited plugged-in station signals representing information constituting the response from the main station. 11. Installation according to claim, characterized in that the transmission equipment of a plugged-in station comprises a keyboard making it possible to establish messages in the form of coded questions, which the main station has installed reception means comprising data processing equipment, and means for receiving the coded keyboard information from a guest plugged-in station and translating it in the form of binary coded signals that can be applied to said data processing means to deduce information therefrom constituting the answer to the question asked, and that means comprising a distributor are arranged at the main station for transmitting coded telegraph signals representing said answer to the question posed for transmission to the invited plug-in station from which said question-shaped keypad information was issued. been transmitted to the main station. 12. Installation according to claim and sub-claim <B> 11, </B> characterized in that said main station comprises a telegraphic distributor making it possible to convert said information constituting the answer to the question asked into coded telegraph signals according to a system by permutation, and that a receiving equipment installed at the plugged-in station which posed the question comprises means intended to receive said coded response to the question signals, indicator means provided at said plugged-in station being variously controlled in accordance with said signals coded constituting the answer to the question asked. 13. Installation according to claim, characterized in that said equipment for transmitting and receiving messages at said main station and at said plugged-in stations comprise means suitable for producing and transmitting outgoing teleprinter messages and a recorder making it possible to record the messages. incoming teleprinter messages, that the receiving means installed at the main station include data processing equipment, that the transmission equipment installed at each of the invited stations includes means suitable for transmitting predetermined functional control signals for indicate respectively whether the message to be transmitted is a keyboard message or a teleprinter message, and that the main station has means sensitive to a functional signal and making it possible to direct the keyboard messages arriving at the main station to said data processing equipment in order to obtain from the latter an answer to the question asked and to direct the teleprinter messages arriving at the main station to the appropriate recorder. 14. Installation according to claim and sub-claim 13, characterized in that the main station also comprises equipment suitable for transmitting predetermined functional signals serving to indicate respectively whether the message to be transmitted from said main station is keyboard information constituting a response to a question asked or a teleprinter message, means being provided at the plugged-in station which are responsive to the aforesaid last mentioned functional signals for directing the information constituting the answer to the question posed and coming from the main station for selectively actuating indicator means corresponding to said plugged-in station and for directing teleprinter message signals from the main station to a recorder installed at the plugged-in station. 15. Installation according to claim and sub-claims 13 and 14, characterized in that the data processing equipment installed at the main station is established so as to receive incoming signals transmitted under the control of a keyboard to the plugged-in station to convert these signals into binary coded information in order to extract from said data processing equipment information constituting an answer to the question asked, and the main station has means making it possible to translate said answer to the question into a binary code to give Permutation coded telegraph signals which must be transmitted to the indicating means installed at the connected station. 16. Installation according to claim and sub-claims 14 and 15, characterized in that said equipment for transmission and reception of messages installed at said main station and at said plugged-in stations comprise telegraph-type tape transmitter means and distributor means making it possible to produce and transmit teleprinter messages, and a recorder to record incoming teletypewriter messages. 17. Installation according to claim, characterized by means suitable for preventing the main station from transmitting a teleprinter message to a plugged-in station except when the plug-in circuit is unoccupied or at the end of an invitation cycle. 18. Installation according to Claim, characterized in that the transmission equipment of any station is provided with means suitable for transmitting, at the start of each traffic transmission, a special starting character and also means suitable for transmitting information. other so-called control characters, and it is further provided with control circuits which are made active under the control of a start character, said control circuits being normally engaged when the transmission is stopped, and Guard circuits are provided to ensure that said start character is transmitted again if the normally continuous transmission of a message is interrupted. 19. Installation according to claim, characterized in that each plugged-in station is for view of individual stopping means, and that means are provided at each plugged-in station which come into action while the station is in activity to prevent the Message traffic sent over the plug-in circuit to another plug-in station can act as an invitation command with respect to said particular station. 20. Installation according to claim, characterized in that each station has a plurality of manually operable switches which can be set in various combinations with each station plugged in to establish the invitation signal, in the form of 'a coded character, which is individually intended for the next connected station.