BE480689A - - Google Patents

Description

       

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  IMPROVEMENTS TO TELEPHONE SYSTEMS
In an extended network, such as a national network, there are certain drawbacks to all the selections being determined by the outgoing exchange because of the routing changes, or temporary (congestion of the network. normal routing route), or permanent (new arrangement of the interurban network) which can occur in intermediate exchanges which are sometimes very, ¯4riz far from the originating exchange. It is, on the contrary, preferable that. these routing changes are controlled by the intermediate exchange in which they are to occur.



   It is also preferable, because of these possible routing modifications, that said routing is determined, not by the succession of a certain number of digits, but by the combination of a certain number of digits which represents the position. geographic tion of a certain area.

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   One of the characteristics of the invention resides in the fact that the routing, from an outgoing exchange, of communications intended for different zones which must be reached through the same intermediate exchange, is only controlled until said intermediate exchange, from which are sent the selection signals necessary to cause the continuation of routing, these different zones being considered, for the outgoing exchange, with respect to the intermediate exchange, as constituting a single zone.



   From this arrangement it follows that the numerical combination necessary to determine the routing from the outgoing exchange to the incoming exchange may include a variable number of digits, the smaller the more the arrival point is. generally more distant, if care has been taken, in the context of a national numbering, to give the said numbering a structure based on regional considerations. The smaller the number of characteristic digits, the faster the routing can be determined, which speeds up the selection. On the other hand, when the number of characteristic digits is high, the importance of the translation devices is increased.



   Another characteristic of the invention lies in the fact, with the aim of accelerating the selection and reducing the importance and the number of translators, of temporarily associating with the recorder which receives the requested number, a translator. primary of simplified realization which can receive a small number of digits and which determines the routing of the communication if this number is sufficient to determine it, said translator being taken only after reception by the recorder of the digits which characterize it and being released as soon as it has sent the selection signals commanded by the recorder. The number of primary translators, all identical, is notably lower than that of recorders.



   Another characteristic of the invention lies in the fact that when the number of characteristic digits necessary for

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 determining the routing is greater than the capacity of the primary translator said primary translator chooses a secondary translator from the group corresponding to the first characteristic digits, which receives the sequence of characteristic digits and determines the routing. Secondary translators are divided into different groups which are all accessible to primary translators.



   In order not to significantly increase the transmission time of the communication, it is advantageous to use, for the transmission of translated combinations from the translator to the recorder, a system other than that based on decimal.



   Another characteristic of the invention lies in the use, for the transmission of the combinations in the recorder-translator assembly, of the system described in French patent number 908. 832 filed on March 11, 1941 so as to obtain transmissions that are practically instantaneous.



   It is common practice to provide devices for causing the automatic release of the various components of a communication chain when the selections have not been successful after a determined time interval. However, the time required for the selections depends on several variables and in particular on the number of exchanges through which the communication must pass.



  It is therefore necessary that the time interval provided for the selection can be variable.



   Another characteristic of the invention lies in the fact that the translator transmits to the recorder, in addition to the selection combinations, an additional combination which fixes the duration of the time interval during which the different selections must. be carried out.



   Another characteristic of the invention lies in the fact that when the association of the recorder and the translator, or of the translator stages between them, is made through a finder, the stop circuit of said finder is used for the transmission.

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 a selection signal.



   When the search among the circuits of the normal channel has not found a free circuit, a search is made among the diverted circuits. In order to speed up these searches, while preferably using the normal route, a simultaneous search can be caused among the circuits of the normal route and those of the alternative route. It is thus necessary to establish a common point between the stop circuits of these two channels and, in the case where two normal channels use the same diverted channel, there is a risk of causing false orientations.



   Another characteristic of the invention resides in the fact that the stop circuits of the normal tracks and of the diverted tracks are put in parallel through suitably oriented rectifiers, so as to prevent false orientations in the event that a diverted route is taken for the routing of two calls coming from two different normal routes.



   Other characteristics will emerge from the description which follows, given by way of non-limiting example, with reference to the appended figures which represent:
Fig. l, a single-line diagram showing the general operation of recorders-translators,
Figs. 2a and 2b, which must be considered together, the diagram of a starting recorder,
Fig. 3, the diagram of a primary translator, functioning in connection with the recorder of FIGS. 2a and 2b,
Fig. 4, the diagram of a secondary translator, functioning in connection with the recorder of figs 2a and 2b, and the translator of fig. 3,
Figs. 5a and 5b, which must be considered together, the diagram of an arrival recorder,
Fig.

   6, the diagram of an arrival translator operating in conjunction with the recorder of Figures 5a and 5b,

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Fig. 7, the connection mode of Figures 2a, 2b, 3, 4, 5a, 5b and 6.



   With reference to FIG. 1, we will now describe the general operation of the departure and arrival recorder-translators. The dial pulses, produced by the dial of the calling subscriber, are received in the recorder ED through the selector Se. After receiving the first two digits, the Chl finder, associated with the ED recorder starts up and searches for an available primary translator TP. The ED recorder transforms the first two digits into a continuous signal formed by a superposition of appropriate currents, and transmits this signal to the translator TP, which then determines the various translated combinations necessary for selection and pricing, sends them back to the recorder, then frees itself.

   During this time, the following digits are transmitted by the calling subscriber and received in the recorder. The latter causes the orientation of the associated selector Se, then emits a low-frequency selection signal which is received, if necessary, on the following local selectors, such as Sel. When the outgoing circuit CI is reached, a return signal is emitted and causes ED to transmit a continuous signal, in voice frequency current, intended to route the call through the various transit exchanges. CT, CT '. The orientation of Se, and the preceding selection signals depend on the translated combination transmitted by the translator.



   As indicated in the preamble, it is difficult for the TP translator on his own to determine the various translated combinations necessary for routing the call to the called party's home exchange, the number of these. last which can be reached from the central departure being too high. Therefore, it only controls the orientation of the communication up to an intermediate point, which may, for example, be the CA center of the called party's home area, after which a return signal

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 is transmitted and causes on the part of ED the, retransmission, in the form of frequency mixing ::; all the digits making up the called party's code.



   To speed up this retransmission, two digits are transmitted at the same time: after which the ED recorder becomes free.



   When the central CA is reached, the searcher Ch3, associated with the recorder EA, starts up and proceeds to search for an available TA arrival translator. The called party's code is received directly in said translator through the selector Se 'and the recorder EA.



   After receiving the portion of the code which characterizes the called party's home exchange, or at least the center of the group to which the called party belongs, the TA translator determines the various translated combinations necessary for routing the call to 'to said central, transmits them to EA, then frees itself.



  As the central CA only serves a few groups, the number of combinations to be translated remains low, and a single translator stage will generally suffice. The recorder EA then causes the selector Se 'to be oriented, then retransmits the translated digits, as the various selection stages are ready to receive them, first in the form of low frequency currents, for local selectors such as Se'1, then in the form of voice frequency currents, for the remote exchanges.



   When the first two digits, received by the translator TP, are insufficient to determine the routing of the call to the central office CA, a secondary translator TS, chosen by said digits, is brought into service. The searcher Ch2, associated with this translator, starts up and searches for the calling primary translator TP. The next two digits are received in the secondary translator TS, which determines the different translated combinations necessary for the orientation of the communication and retransmits them to the ED recorder through TP.

   Of course, it is necessary

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 provide at least as many secondary translators as there are combinations of the first two digits insufficient to control the selections to the central CA; it is even necessary to provide more, in the event that several subscribers simultaneously number the same first two digits. The two translators TS and TP are then released and the recorder ED retransmits the various translated and untranslated digits as indicated previously.



   We will now, referring to fig. 2a, 2b, 3, 4, 5a, 5b and 6, give a detailed description of the start and finish recorders - translators.



   In the descriptions which follow, the relay contacts which are closed when the relay to which they are associated is energized, i.e. when sticking, are indicated by preceding the number of the spring with the letter T, and the contacts which are closed when the relay is not energized, that is to say in the rest position, by preceding the number of the spring by the letter R.



  On the other hand, the contact springs associated with a given relay are designated by having the relay reference follow one of the numbers 1 to 9.



   The combiner contacts are represented by two closely spaced circles to which the circuits completed by the combiner of the combiner lead. The indications mentioned opposite each contact relate to the combiner with which this contact is associated, the positions of the wipers for which the combiner closes the contact in question, and the wiper of the combiner which closes said contact.



   Each combiner is a rotary type switch whose wipers are moved by the action of a rotating electro.



  For the sake of simplification, the same letter will be used to designate the rotating electro and the combiner actuated by said electro.



   The battery normally used for powering

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 different relays, and whose negative pole is represented by an arrow, has its positive pole at, earth; nevertheless, a special low-capacity battery has also been provided, the negative pole of which is connected to the positive pole of the previous one and which is used in particular in the stop circuit of the researcher associated with the secondary translator. In the course of the text, the normal supply battery will be designated by the reference Btl and the special battery by the reference Bt2.



   To simplify the drawings, it has been necessary to group the connecting wires, in particular those which connect two neighboring figures, in cables. The different wires that are part of a specific cable are designated by following the cable reference with one of the numbers 1 to 9.



   When the recorder, shown in fig. 2a and 2b, is at rest, all its relays are de-energized and its various rotary switches in position 0. A battery is then put on wire 743, through the, resistor Rell, trotters has switches T, S, A, U in position 0 and R 301, so as to indicate to selector Se that the recorder is unoccupied.



   When said selector is engaged, an earth is placed on wire 742 and causes the excitation of relay 16 through, towards contact R 304. At T 161, relay 16 prepares the operation of switches U and T; in T 162, it places a general maintenance earth on the mgl wire and completes the following two circuits: battery, lower winding of 34, wiper c of switch U in position 0, T 162, earth, and battery, rotation electro A and its rotation contact ra, wiper of switch A in position 0, T 162, earth; in T 163, it prepares the stop circuit of the researcher Ch 1.



   The relay 34 prepares at T 341 the circuit for receiving the dialing pulses; in T 342, it causes the excitation of relay 38; in T 343, a holding circuit is prepared.

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   The rotation electro A, by the play of its contact ra, causes the advancement of its wipers in position 1 and stops, its advancement circuit then being open on the wiper e.



  He prepares, on this position, the reception of the 1st digit on the appropriate organs.



   Relay 38 prepares in T 382 and T 383 the circuit for receiving the numbering pulses on the various marker relays, in T 384 the circuit for advancing switch A between each digit:
An appropriate signal is transmitted to the caller on the following circuit: wire 751, capacitor C1, wiper e of switch A in position 1, 'trotter b of switch U in rest position, wire 743, which indicates to the caller that' it can transmit the code of its correspondent.



   The numbering is transmitted in the form of battery pulses on the following circuit: wire 741, R 331 ', relay 21, T 341, earth. The relay 21 beats and causes in T 211 the advancement of the switch U by a number of steps corresponding to the number received. As soon as the first pulse has been received, relay 34 has had its excitation circuit open on the rest position of switch U, but it is then maintained by: earth, upper winding of 34, T 343, resistance Re 12, battery , despite the brief short-circuits which it undergoes in R 211, due to the fact that it is slowed down by said short-circuits. After the reception of the first digit, it takes off, having its winding of maintains long short-circuited in R 211.



   We will assume that the first digit received is 9. Switch U then came to position 9.



   Relay 34, when taking off, complete, in R 341 and R 342, the following two circuits: battery, relay 14b, wiper b of switch A in position 1, wiper a of switch U in position 9, T 382, R 341, Earth; battery, relay 14d, wiper d of switch A in position 1, wiper b of switch, U in position

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 9, T 383, R 342, earth; in R 344, it completes the circuit of electro A by: battery, electro A, T 384, R 344, T 162, earth.



   Relays 14 b and 14 d complement the following maintenance circuits battery, relay 14b, T 142 b, T 162, earth, and battery, relay 14d, T 144 d, T 162, earth; they prepare, in T 142 b and T 144 d, the switching on of the retransmitting relays 18 and 20.



   Relay 38, having its open circuit at T 342, releases its armature at the end of the time allotted by its takeoff delay.



  In R 381, it causes the switch U to return to rest on the following circuit: battery, electro U and its rotation contact ru, wiper of switch U in positions 9 and 10, R 381, T 161, earth; in T 384, it opens the circuit of the rotation electro A which releases its armature and advances its wipers, in position 2, thus preparing the reception of the second digit.



   When switch U has returned to idle, relay 34 is re-energized on the circuit already indicated, resulting in T 342 la, re-energization of relay 38. With the excitation of the marker relays and the position of the switch A near, the recorder is in the same position as that it occupied before the reception of the first digit.



   The other digits are received as indicated for the first; switch A advances one step after each digit in order to switch on the marker relays intended to receive the next digit.



   If we assume, for example, that the code received is "9342.5646", the marker relays that come to the collage are as follows:
14b and 14d for the first digit
26 c for the second digit
32 d for the third digit
36 b for the fourth digit
39 a, and 39 b for the fifth digit

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11 a and 11 c for the sixth digit
13 d for the seventh digit
15 a and 15 c for the eighth digit
The operations relating to the search for a primary translator will begin when the third digit is received and continue independently of those relating to the registration.

   When combiner A is in position 3, the following two circuits are completed: battery, relay 31, wiper e of combiner A in position 3, wiper i of combiner S in position 0, T 162, earth, and battery, electro S and its rotation contact ra, wiper h of combiner S in rest position, wiper e of combiner A in position 3, wiper i of combiner S in position 0, T 162, earth.



   Relay 31 sticks and combiner S advances to position 1.



   The translator finder Chl starts up, the following advancement circuit being completed: battery, electro Rl and its rotation contact rl, wiper b of the combiner S in position 1, R 285, R 251, T 162, earth.



   The Chl finder has a number of positions, all of which give access to identical primary translators. To simplify the drawing, only one of these positions has been shown.



   When the rubbers of said finder reach the level of an available primary translator, such as that of FIG. 3, the following circuit is completed: earth, T 163, wiper a of the combinator S in position 1, series winding of relay 25, wiper Tl and associated bank contact, wire 762 'through cable 76, (fig. . 3), R 631, resistor Re 21, battery. Relay 25 comes to bonding. In R 251, it opens the advancement circuit of the seeker Chl, which stops on the position considered; T 251, it completes the circuit of relay 28 through contacts R 124, T 251 and T 162; in T 252, it short-circuits its upper winding to large

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 resistance, so as to lower the test potential and to mark the occupation on the translator engaged.



   The relay 28 attracts its armature, at the end of the time allotted by its delay in bonding. In T 282, it short-circuits the relay 25 and ma, initiates the marking of the occupation on the transducer in engagement: in T 283, it causes the advancement of the combiner S in position 2 on the following circuit: battery, electro S and its rotation contact rs, wiper i of the combiner S in position 1, T 283, mgl wire, T 162, earth; in T 284, it causes the sticking of relays 59 and R 285, it cuts the advancement circuit of the researcher Chl, which would otherwise be closed in R 251;. in T 286, a circuit of maintenance.



   Relay 59 connects, through its various work contacts, the ED recorder to the TP translator. In T 591 ', it completes the following circuit: battery, relay 61, (pin 3), R 633, wire 766 through cable 76 (fig. 2a), bench contact and TEI wiper, T591', conductivity element one-sided Q 11, left winding 56, bottom winding 58, one-sided conductive element Q 14, earth. Relay 61 sticks, but relays 56 and 58 remain idle due to the high resistance of relay 61.



   On position 2 of combiner S, the following circuits are completed: battery, relay 18, wiper b of combiner S in position 2, T 142 b, T 162, earth; battery, relay 20, wiper d of combiner S in position 2, T 144 d, T 162, earth; battery, relay 19 ', switch g of the combiner S in position 2, T 263 c, T 162, earth.



  Relays 18 and 20 correspond to the first digit received (9), and relay 19 'to the second digit (3).



   In the translator TP, the relay 61 is completed, in T 611, the following holding circuit: battery, relay 61, T 611, wire 762 'through cable 76, (pin 2b), bench contact and slider Tl, T 282, earth; in T 612, it causes the excitation of relay 63;

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   T 613, it completes the circuit of relay 62 through contact R 734 '.



   The first two digits are marked in the translator by energizing relays 68,65, 70,72, 71 on the following circuits: earth, generator Ge 1 (fig. 2b), R 312, left winding of 29, one-sided conductive element Q 15, T 182, resistor Re 13, T 593 ', wiper I 11 and bench contact, wire 768 through cable 76 (fig. 3), R 731, rectifier Q 21, lower winding 68, right winding 66, rectifier Q 22, earth, for relay 68; generator Ge 1, (fig. 2b '), R 312, left winding 29, rectifier Q 14', T 201, T 594 ', wiper 1 12 and bench contact, wire 769, through cable 76, (fig. 3), R 731 ', rectifier Q 23,' lower winding 65, earth, for relay 65;

   earth, generator Gel, R 312, left winding 29, rectifier Q 16, R 171 ', T 191', T 595 ', wiper 1 13 and bench contact, wire 761' through cable 76, (fig. 3), R 734, rectifier Q 25, lower winding 72, right winding 70, rectifier Q 26, earth, for relays 70 and 72; Gel generator, R 312, right winding 29, rectifier Q 13 ', R 181', T 191 ', T 595, wiper 1 13 and bench contact, wire 761' through cable 76, R 734, rectifier Q 27, top winding 71, right winding 70, rectifier Q 24, earth, for relays 71 and 70.



   Relay 66 remained at rest, due to the high value of resistor Re 13.



   Recorder relay 29 is energized in series with translator marker relays and completes the following circuit in T 291 and T 292: battery, electro S and its rotation contact rs, T 292, T 291, earth. Said electro attracts its armature and is then held through resistor Re 14. '
From the examination of the different circuits, we can deduce the following two tables which indicate the correspondence between the

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 digits received, the relays energized in the recorder, the different polarities placed on wires 768, 769, 761 ', and the relays energized in the translator.
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  768 <SEP>: <SEP> 769 <SEP>: <SEP> 761 ':
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  <Desc / Clms Page number 15>

 
In the preceding tables, the sign + designates a pulsed current comprising only positive half-waves, the sign-, a pulsed current comprising only negative half-waves, and the abbreviation Alt an alternating current. The letter R following said signs or abbreviations indicates that a high resistance is inserted in the marker relay circuit in order to prevent the energization of marginal relays such as 66 and 70.



   Note that the same wire 769 is used for both the transmission of the first and second digit; polarity - being exclusively reserved for the first digit and + polarity for the second.



  If these two polarities are to be transmitted simultaneously, it is as if an alternating current were sent, the negative alternations energizing the first digit relay, and the positive alternations the second digit relay.



   In the translator, the relay 65 is completed by a holding circuit by: battery, upper winding of 65, T 651, T 613, earth. The other marker relays 68, 70, 71 and 72 are maintained in a similar fashion.



   Relays D 9 and D'3 are then energized on the following circuits: battery, relay D9, wire 779 through cable 77, T 683, R 673, T 652, earth, for relay D 9, and battery, relay D'3, connection x, wire 7893, through cable 78, work contact D.93, associated with relay D 9, T 703, T 722, T 722, T 712, R 692, earth.



   As can be seen from the examination of the various circuits, the ten relays D 1, D2 ----- D9, DO are energized one or the other depending on the nature of the first digit received, the relay Dl if the number 1 has been received, D2 if the number 2 has been received, etc. These ten relays each have ten working contacts, i.e. one hundred contacts in total, connected respectively to the one hundred cable wires 78. Depending on the combination of the first two digits received, one of the hundred wires is grounded, through a working contact of one of the re-

  <Desc / Clms Page number 16>

 lais Dl to D10, and through the conta, cts of the marker relays 69 to 72, which recorded the second digit. But, in general,!, The number of zone centers to be reached, and therefore that of the possible routes that the translator must give, is less than 100.

   A certain number of relays are provided for, such as D'l, D'2 ---- D'n, less than 100, which are connected to the various wires of the cable 78 by appropriate connections, such as x, the same relay such as D'3 can be connected to two or more of the wires of cable 78.



  Each of these relays corresponds to a determined route.



   The translator then sends back to the recorder, still in the form of currents of appropriate polarities, four translated combinations, the first corresponding to the selections to be made in the central considered, the second corresponding to external selections, the third to pricing and the fourth for set the time after which the recorder must free itself, if, for one reason or another, the various selections are not made in time.



   The transmission mechanism of the first translated combination is as follows. Currents of appropriate polarities are sent by the generator Ge 2, through the transformer TR2, on the various wires 791 to 796. Rectifiers Q 30 to Q 33 make it possible to obtain, from the alternating current supplied by the generator, pulsed currents of appropriate direction; the intensity of said currents is higher or lower depending on whether the 1991 or 1992 taps are used on the secondary of transformer TR2.



    The current diLs are then routed through appropriate connections, such as y, yl, y2, wire 80, NO contacts D '31 to D' 34 of relay D'3, wires 764 and 765, to wipers 0 14 and 0 15 of the researcher Chl, and cause the excitation of one or more of the relays 49.50, 51, 52.53, 54.57 and 57 '. Relays 49 and 53 are energized under the effect of a pulsed current in a positive direction (the positive direction being chosen, by convention, like that of the

  <Desc / Clms Page number 17>

 currents going from the translator to the recorder) the relays 50 and 54 are energized under the effect of a negative pulsed current; the marginal relays 51, 52, 57 and 57 'only come to the bonding when the current passing through them reaches a determined intensity, which occurs when using the 1991 plug.

   Relays 49 to 52 provide eight different combinations:
49
49 - 51
50
50 - 52
49 - 50
49 - 51 - 50
49 - 50 - 52
49 - 51 - 50 - 52
The relays 53,54, 57,57 'also allow eight combinations which gives a total of 8 x 8 = 64 combinations which will be used subsequently for the orientation of the local selection stage (s).



   The relay 60 is provided to double the relay 53, which does not have enough contacts.



   The transmission mechanism of the second translated combination from the translator to the recorder is performed in a similar fashion, but using wires 761,762, 763 and relays 41 to 48. The relays 41, 43, 44, 48, 45, 47 are energized or not depending on the direction of the alternations received; the relays 42, which is in series with one of the relays 41 or 43, are energized if the current intensity is sufficient, as is the relay 46.

   If we adopt the same conventions as before with regard to the correspondence between the different polarities and the figures they represent, we obtain the following two tables:

  <Desc / Clms Page number 18>

 
 EMI18.1
 
 <tb> Selections <SEP> exterior <SEP> rubbers <SEP> Relay <SEP> excited
 <tb>
 <tb>
 <tb>
 <tb> 1st <SEP> digit <SEP> translated <SEP>: <SEP> 011 <SEP> 012
 <tb>
 <tb>
 <tb> 1 <SEP> fR <SEP> 41
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP> - <SEP> R <SEP> 43
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> Alt <SEP> 41 <SEP> - <SEP> 42 <SEP> - <SEP> 43
 <tb>
 <tb>
 <tb>: <SEP>: <SEP>:
 <tb>
 <tb> 4 <SEP>: <SEP>: <SEP> + <SEP>: <SEP> 44
 <tb>
 <tb>
 <tb>
 <tb>: <SEP>: <SEP>:
 <tb>
 <tb> 5 <SEP>: <SEP> Alt <SEP> R: <SEP>:

    <SEP> 41 <SEP> - <SEP> 43
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> + <SEP> 41-42
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP>: <SEP> + <SEP> R <SEP>: <SEP> + <SEP>: <SEP> 41 <SEP> - <SEP> 44
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP> 42 <SEP> - <SEP> 43
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 9 <SEP> - <SEP> R <SEP>: <SEP> 43 <SEP> - <SEP> 44
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> Alt <SEP> 41 <SEP> - <SEP> 42 <SEP> - <SEP> 43 <SEP> - <SEP> 44
 <tb>
 <tb>
 <tb>
 <tb> Selections <SEP> exterior: <SEP> rubbers <SEP> Relay <SEP> excited
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 2nd <SEP> digit <SEP> translated <SEP> 0 <SEP> 13 <SEP> 0 <SEP> 12
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP> + <SEP> R <SEP>:

    <SEP> 45
 <tb>
 <tb>
 <tb> 2 <SEP> - <SEP> R <SEP> 47
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP> Alt <SEP> 45 <SEP> - <SEP> 46 <SEP> - <SEP> 47
 <tb>
 <tb>
 <tb> 4- <SEP> 48
 <tb>
 <tb>
 <tb> 5 <SEP> Alt <SEP> R <SEP>: <SEP> 45 <SEP> - <SEP> 47 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> 45 <SEP> - <SEP> 46 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP> + <SEP> R <SEP>: <SEP> - <SEP>: <SEP> 45 <SEP> - <SEP> 48
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP> 47 <SEP> - <SEP> 46
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> - <SEP> R <SEP>: - <SEP>: <SEP> 47 <SEP> - <SEP> 48
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> Alt <SEP>:

    <SEP> 45 <SEP> - <SEP> 46- <SEP> 47 <SEP> - <SEP> 48
 <tb>
 
We thus obtain 10 x 10 = 100 combinations which will be used later for the external selections.



   As before, the same wiper 0 12 is used at the

  <Desc / Clms Page number 19>

 times for two digits, polarity t being exclusively reserved for the first digit, and polarity - for the second. This saves a wiper.



   The combination relating to pricing is transmitted directly to a metering device associated with the selector, on the following circuit: generator Ge 2 (fig. 3), transformer TR 2, rectifiers Q 30 to Q 33, wires 791 to 796, connections suitable such as z, cable 81, work contacts D'38 and D'39 associated with relay D'3, wire 767 through cable 76 (fig. 2b), bench contact and wiper CRl, T 592 'and wire 746.



   The combination relating to the time delay is transmitted on the following circuit: generator Ge2, transformer TR2, rectifiers Q 30 to Q 33, wires 791 to 796, connections such as u, cable 82, work contact D'30 of relay D '3, wire 766 through cable 76, bench contact and wiper TEl, T 591', rectifier Q 13, right winding 65, bottom winding 58, rectifier Q 12, earth, or rectifier Q 11, left winding 56, lower winding 58, rectifier Q 14, earth. The relays 55 or 56 are energized or not depending on the direction of the current received, the relay 58 only operating if the intensity of said current is sufficient.

   We can thus obtain 7 different combinations:
 EMI19.1
 
 <tb> N <SEP> of <SEP> the <SEP> combination <SEP> Slider <SEP> TE <SEP> 1 <SEP> Relay <SEP> excited
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> None <SEP> None ' <SEP> ' <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP> ¯ <SEP> R <SEP> 55
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP> 55 <SEP> - <SEP> 58 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP> - <SEP> R <SEP> 56
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 56 <SEP> - <SEP> 58 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP> Alt <SEP> R <SEP> 55 <SEP> - <SEP> 56 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> Alt <SEP> 55 <SEP> - <SEP> 56 <SEP> - <SEP> 58
 <tb>
 

  <Desc / Clms Page number 20>

 
Note that, due to the absence of any rotary or other switch, the transmission of the numbered code in the translator,

   and the retransmission of the various combinations by the translator took place practically instantaneously.



   The marker relay 41, if it has energized, is completed by a battery holding circuit, left winding of 41 T 411, upper winding of relay 12, T 162, earth. The other marker relays complement the analog hold circuits.



   Relay 12 is energized in series in the circuit of the various marker relays. In T 121, a maintenance circuit is completed by battery, lower winding of 12, T 121, T 162, earth; in T 122, it completes the following circuit of switch T: battery, electro-rotation T, T 122, R 351, Ca 12 cam, earth; in T 123, it short-circuits its upper winding to increase the ampere-turns in the various holding windings of the marker relays; in R 124, it opens the circuit of relay 28, which takes off; in T 125 and T 127, it prepares the sending of the seizure signal to the remote exchanges.

   Relay 59, having its circuit open at T 284, takes off and disconnects by its various contacts the translator's recorder, which is released in a known manner: it also opens, at T 593 ', T 594', T 595, 'the circuit of relay 29, which takes off.



   Relay 29 opens at T 291 the circuit of electro-rotation S, which releases its armature and moves the wipers of the associated combiner to position 3.



   The combiner S then advances to position 4 on the following circuit: battery, electro S and its rotation contact r, R 281, wiper i of combiner S in position 3, T 162, earth.



   Relay 23 is energized on its upper winding, through wiper b of combiner S in position 4 and T 162. In T 234, it completes the following advance circuit of selector Se associated with the recorder: earth, T 162, wiper b of combiner S in position 4, R 221, R 241, T 234, wire 741 'and battery through electro

  <Desc / Clms Page number 21>

 of rotation (not shown) of selector Se.



   It will be assumed that, among the four relays 49 to 52 corresponding to the orientation of the first selector, only the relays 49 and 50 are glued. When the wipers of the selector associated with the recorder pass in front of a bank contact connected to wire 841 through cable 84, an earth is placed on said wire, and the following circuit is completed: earth on wire 841, R 601 ', R 523, R 512, T 502, T 492, wiper a of the combiner S in position 4, T 232, one-sided conductivity element Q 17, series windings of relay 22, wire 742 'and emergency battery (not shown) at through the Se selector.



   Relay 22 comes to bonding. In R 221, it opens the advance circuit of selector Se, which stops in the position considered; in T 221, it prepares the connection of the wipers; at T 222, it places its high resistance lower winding in parallel with the low resistance lower winding of relay 23, to lower the test potential and mark the busy line on the in-tune.



   The relay 23 takes off, its two windings producing equal and opposite sign flows. In R 231, it places an earth on wire 749, through T 221, wiper b of switch S in position 4, mgl wire, T 162 and earth, in order to complete the circuit of the line wires in selector Se; at T 232, it opens the circuit of 22 which takes off, arrangements being made in the selector to prevent an untimely restart. Relay 23, having its opposition winding open at T 222, re-energizes again. In T 231, it completes the following circuit: battery, median winding of 40, T 231, and earth put on wire 749 by the selector, when the circuit of the line wires has been completed.



   The relay 22 does not re-energize, because the selector has put an earth polarity on the wire 742 'after the connection of the line wires.

  <Desc / Clms Page number 22>

 



   Relay 40 comes to bonding. In T 401 and T 403, it causes the emission, on the wires 744 and 745, of currents of appropriate polarity, intended to cause the possible orientation of other selection stages in the office in question. These currents are sent by the generator Ge'l, to. through the rectifiers Q16 ', Q17', the various contacts of the marker relays 49, 50, 51, 52, T 401 and wire 744, on the one hand, and the rectifiers Q 18 and Q 19, the various contacts of the marker relays 53 , 54, 57, 57 ', T 403 and wire 745 on the other hand. The resistors Re 15 to Re 18 are designed to modify the intensity of the emitted currents.

   In T 402, relay 40 completes the following holding circuit: earth, T 162, mgl wire, 40 lower winding, T 402, resistors Re19 and Re20 in parallel, wires 747 and 748 and earth through local selection stages other than the first; in T 404, it completes the following circuit: battery, electro S and its rotation contact rs, wiper i of the combiner S in position 4, T 404, T 162, earth. The combiner S moves its sliders to position 5.



   Relay 23 takes off, with its circuit open on trotter b of combiner S, and opens the circuit of the middle winding of relay 40. One or more of the relays such as 17,17 ', 18, 18', 19, 19 ', 20,20' are energized through the wipers of the combiner S on position 5, and the contacts of the marker relays 41 to, 48.



  Relays 17 to 20 'prepare by their contact T 174, T 173, T 174', T 173 ', T 184, T 183, T 184', T 183 ', T 193, T 192, T 193', T 192 ', T 203, T 202, T 203', T 202 'the emission of currents of frequencies fl to f8 intended to cause the orientation of the selectors in the various transit exchanges. Examination of the various circuits makes it possible to establish the following table, giving the correspondence between the energized relays, the frequencies retransmitted, and the figures represented by said frequencies.

  <Desc / Clms Page number 23>

 
 EMI23.1
 
 <tb>



  1st <SEP> digit <SEP> translated <SEP> Frequencies
 <tb>
 <tb> for <SEP> selections <SEP> ex- <SEP> Relay <SEP> excited
 <tb>
 <tb> tieures <SEP> retransmitted
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP> 41 <SEP> 17 <SEP> f1
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP> 43 <SEP> 18 <SEP> f2
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP> 41-42-43 <SEP> 19 <SEP> f3
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP> 44 <SEP> 20 <SEP> f4
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP> 41-43 <SEP> 17-18 <SEP> f1 <SEP> f2
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> 41-42 <SEP> 17-19 <SEP> f1 <SEP> - <SEP> f3
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP> 41-44 <SEP> 17-20 <SEP> f1 <SEP> f4
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP> 42-43 <SEP> 19-18 <SEP> f2 <SEP> f3
 <tb>
 <tb>
 <tb>
 <tb> 9 <SEP> 43-44 <SEP> 18-20 <SEP> f2 <SEP> f4
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> 41-42-43-44 <SEP> 19-20 ' <SEP> f3- <SEP> f4
 <tb>
 
 EMI23.2
 ---------------------. -------- ...----------------- --.------------------

  
 EMI23.3
 
 <tb> 2nd <SEP> digit <SEP> translated <SEP>: <SEP> Frequencies
 <tb>
 <tb>
 <tb> for <SEP> selections <SEP> ex- <SEP> Relay <SEP> excited
 <tb>
 <tb>
 <tb> tieures <SEP> transmitted
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP> 45 <SEP> 17 ' <SEP> f5
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP> 47 <SEP> 18 ' <SEP> f6
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP> 45-46-47 <SEP> 19 ' <SEP> f7
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP> 48 <SEP> 20 ' <SEP> f8
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP> 45-47 <SEP> 17'-18 ' <SEP> f5 <SEP> - <SEP> f6
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> 45-46 <SEP> 17'-19 ' <SEP>.

    <SEP> f5 <SEP> - <SEP> f7
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP> 45-48 <SEP> 17'-20 ' <SEP> f5 <SEP> - <SEP> f8
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP> 47-46 <SEP> 18'-19 ' <SEP> f6.- <SEP> f7
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 9 <SEP> 47-48 <SEP> 18'-20 ' <SEP> f6 <SEP> - <SEP> f8
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> 45-46-47-48 <SEP> 19'-20 ' <SEP> f7 <SEP> - <SEP> f8
 <tb>
 
When the last local selection stage is oriented, earth is removed on wires 747 and 748, and relay 40 is lifted off.

  <Desc / Clms Page number 24>

 



  In T-401 and T 403, it suppresses the emission of the polarities which have been used to cause the orientation of the local selection stages; in R 401 and R 403, it allows the emission of frequencies fl to f8 on the following circuits: generators Gfl to Gf8, resistors Re 13 'to Re 19' and Re 11 "to Re 19", working contact for relays 17 at 20 ', R 351' and R 353 ', TRI transformer, R 401 and R 403, wires 744 and 745. As results from the preceding table, the four frequencies f1 to. f4 are used for sending the first translated digit, and the next four f5 to f8 for sending the second translated digit, these two digits being sent simultaneously:
On these selection signals is superimposed a tap frequency, emitted by the generator Gfs through the contacts T 127 and T 125.

   These tap and selection currents are emitted continuously and cause the orientation of the selectors in the various transit exchanges.



   When the call has been routed to the home area of the called subscriber, a signa! in return is sent from said zone to the office in question, and reaches, through wires 747, 748, transformer TR'l, to detector DET 1. The latter causes the closing of the contact det 11, which completes the circuit of the relay 35 'through the contact R 353 The relay 35' sticks, suppresses in R 351 'and R 353' the emission of the tap signals and selection and prepares the relay 35 circuit at T 352 '.



   When the feedback signal ends, the contact det 11 is open; relay 35, short-circuited, is energized and relay 35 'remains in the following circuit: battery, relay 35' and 35 in series, T 352, mgl wire, T 162, earth. In R 351, the relay 35 opens the advance circuit of the switch T; at T 352, it causes switch S to advance to position 6 on the following circuit: battery, electro S and its rotation contact rs, wiper i of combiner S to position 5, T 352, mgl wire, T 162, earth; in T 354, it switches on the Ca 11 cam.



   When the combiner S leaves position 5, the relays 17

  <Desc / Clms Page number 25>

 at 20, 17 'to 20' take off. When S goes to position 6, these various relays will be re-energized depending on the nature of the first two digits received. In the example considered, these figures were a
9 and a 3, which corresponded, as has been indicated, to the excitation of relays 14b, 14d and 26c. The relays 18, 20, 19 'will then be energized on the following circuits: battery, relay 18, wiper b of the combiner S in position 6, T 142b, T 162, earth, for relay 18; relay 20, wiper d of the combiner S in position 6, T 144 d, T 162, earth, for relay 20; relay 19 ', wiper g of the combiner S in position 6, T 263 c, T 162, @, earth, for relay 19'.

   Relays 18 and 20 prepare in T 184,
T 183, T 203, T 202, the emission of the frequencies f2 and f4, which correspond to the number 9; relay 19 'prepares in T 193' and T 192 'the emission of the frequency f7, which corresponds to the number 3.



   By examining the different circuits, we can establish the following tables of correspondence between the energized relays, the transmitted frequencies and the untranslated figures represented by the said frequencies.
 EMI25.1
 
 <tb>



  1st <SEP> digit <SEP>: <SEP> Relay <SEP> excited <SEP> frequencies
 <tb>
 <tb> no <SEP> translated <SEP> issued
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP> 14 <SEP> a <SEP> 17 <SEP> f1
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP> 14 <SEP> b <SEP> 18 <SEP> f2
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP> 14 <SEP> c <SEP> 19 <SEP> f3
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP> 14 <SEP> d <SEP> 20 <SEP> f4
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP> 14 <SEP> a <SEP> 14 <SEP> b <SEP> 17 <SEP> - <SEP> 18 <SEP> fl <SEP> - <SEP> f2 <SEP>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> 14 <SEP> a <SEP> 14 <SEP> c <SEP> 17 <SEP> - <SEP> 19 <SEP> fl <SEP> - <SEP> f3 <SEP>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP> 14 <SEP> a <SEP> 14 <SEP> d <SEP> 17 <SEP> - <SEP> 20 <SEP> fl <SEP> - <SEP> f4 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP> 14 <SEP> b <SEP> 14 <SEP> c <SEP> 18 <SEP> - <SEP> 19 <SEP> f2 <SEP> - <SEP> f3 <SEP>
 <tb>
 <tb>
 <tb>
 <tb> 9 <SEP>:

    <SEP> 14 <SEP> b <SEP> 14 <SEP> d <SEP> 18 <SEP> - <SEP> 20 <SEP> f2 <SEP> - <SEP> f4 <SEP>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> 14 <SEP> c <SEP> 14 <SEP> d <SEP> 19 <SEP> - <SEP> 20 <SEP> f3 <SEP> - <SEP> f4 <SEP>
 <tb>
 

  <Desc / Clms Page number 26>

 
As can be seen from the examination of the table above, the frequencies transmitted, for each digit, correspond to the frequencies received, so it is now a question of retransmission without translation.



   A similar picture could be drawn for the untranslated second digit; relays 14 a to 14 b would then be replaced by relays 26 a to 26 d, relays 17 to 20 by relays 17 'to 20' and frequencies fl to f4 by frequencies f5 to f8.



   When the Ca cam, It closes its contact, the following circuit is completed: earth, Ca cam 11, T 354, R 371, R 311, 37 'left winding, battery. Relay 37 'sticks together and prepares the circuit for relay 37 at T 371'. When the cam Ca 11 opens its contact, the relay, is 37 'is maintained, and the relay 37 is energized in the following circuit: battery, relay 37' and 37 in series, T 371 ', T 162, earth; relay 37 switches the cam circuit on relay 27 to RT 371
When the latter closes its contact again, the relay 27 is energized by: earth, cam Ca 11, T 354, T 371, relay 27, battery.



   The relay 27 allows, in T 271 and T 272, the simultaneous return of the first two untranslated digits and completes, in T 273, the circuit of the rotation electro S.



   When the Ca 11 cane opens its contact again, the relay 27 takes off, ends, in T 271 and T 272, the transmission of the first two untranslated digits and opens in T 273 the electronic circuit. lectro S, which moves its rubbers to position 7.



   As can be seen, the emission of the frequencies corresponding to the first two digits persisted throughout the duration of a closing of the Ca 11 cam.



   Due to the passage of the combiner S from position 6 to position 7, relays 17 to 20 and 17 'to 20' will be in

  <Desc / Clms Page number 27>

 a situation which depends on the nature of the third and fourth digits received.



   Other untranslated digits are returned two by two as indicated for the first two. Relay 27 beats at the rate of cam Ca 11; when it is excited, it allows in T 271 and T 272 the simultaneous sending of two digits and completes in T 273 the circuit of the electro S; when it releases, it ends the transmission and opens the circuit of S, which advances its rubbers by one step and prepares the transmission of the next digit.



   The 3rd and 4th digits are sent to position 7 of combiner 5, the 5th and 6th digits to position 8, the 7th and 8th digits to position 9, after which said combiner moves to position 10.



   The following circuit is then completed: battery, resistor Re 11, upper winding of 30, wiper i of the combiner S in position 10, T 162, earth. Relay 30 comes to bonding. In T 303, a maintenance circuit is completed by: earth, T 303, upper winding of 30,, resistor Re 11, battery; in T 301, it prepares the short-circuiting of its excitation winding; in T 302, it prepares the release of the combiners A, S and T; enR 304, it opens the circuit of relay 16, which takes off and makes a cut on wire 742, which disconnects the selector from the recorder.



   The relay 16, when taking off, completes in R 161 the following release circuit of combiner A: battery, electro A and its rotation contact ra, wiper f of said combiner in positions 9 and 10, R 161, T 302, earth; by opening its contact T162, it prepares the take-off of all the marker relays, which are still held through the wiper i of the combiner S in position 10 and T 303; R 164, it completes the following circuit for releasing the combiner S: electro S and its rotation contact rs, wiper j of said switch in position 10, R 164, wire 200, T 302, earth.

  <Desc / Clms Page number 28>

 



   When the slider S has crossed the position 10, it opens, by its slider i, the circuit of all the relays except 30 and 38.



  In R 122, relay 12 completes the following release circuit for switch T: battery, solenoid T, R 122, rotary contact rt, wiper b of switch T in positions 1 to 10, wire 200, T 302, earth. Relay 38 takes off, having its circuit open at T 342.



   When the switches A and T have returned to rest, the relay 30 takes off, having its holding winding short-circuited by T 301 and the wipers has various switches in the rest position. it resets the availability battery on wire 743 to R. 301. The recorder is completely released.



   It has been assumed, in the previous description, that the first two digits received were sufficient to determine the differences translated combinations necessary for the routing of the call; the translator's capacity may therefore be limited to 100 numbers. But there may be cases where three or even four digits are needed. In order to avoid in this case the use of too cumbersome translators, a so-called “secondary” translator is associated with the primary translator intended to receive all the combinations of four digits starting with the same two first digits.



  If the first two digits received, "94" for example, are not sufficient to determine the different combinations translated, the primary translator is associated with a secondary translator who can receive all the codes beginning with one. of the 100 combinations 9400 to 9499.



   The different operations follow one another as indicated in the preceding ca, s, but the first two digits of the code received are such that it is one of the relays D'nl to D'n4 which comes to the pasting in the primary translator, the D'n3 relay for example -
Relay 73 is energized in series with relay D'n3.

  <Desc / Clms Page number 29>

 



   The D'n3 relay, unlike what happened for the D'l to D'3 relays, has no contact allowing the passage of currents from the Ge 2 generator to the recorder, except for the combination corresponding to the time delay. On the other hand, it completes, through its contact D'n31, the following circuit: earth, R 641, working contact D'n 31, wire 971, (fig. 4), R 961, relay 92, battery; in D'n33, it allows reception of the timing combination on relays 55, 56 and 58 of the recorder in the manner already indicated.



   Relay 73 opens, in R 731, R 731 ', R 734, the circuit of relay 29 of the recorder; it prepares, in T 731, T 731 'and T 734', the reception of the third and fourth digits in the secondary translator; it prepares, in T 732, T 733, T 735, T 732 ', T 733', T 735 'the connection of the two translators to each other; opens in R 734 ', the circuit of relay 62.



   The recorder relay 29, when taking off, opens in T 291 the circuit of the electro S, which moves its wipers to position 3, so as to prepare the sending of the third and fourth digits received on the secondary translator .



   The relay 92 of the secondary translator TS completes, at T 922, the following advancement circuit of the researcher Ch2, associated with the secondary translator: battery, electro R2 and its rotation contact r2, T 922, R 931, R 911, Earth ; T 923, it prepares the stop circuit of said researcher.



   In the recorder, (fig. 2) the combiner S, passing from positions 2 to 3, caused by its wipers a to h a change in the situation of 'relays 17 to 20, 17' to 20 ', said relays occupying maintaining positions corresponding to the third and fourth digits received. If, for example, the third and fourth digits received correspond respectively to the energization of the relays 32a and 36b, the relays 17 and 18 'stick to the following circuits. : battery, relay 17, wiper a of the S combiner in position 3,

  <Desc / Clms Page number 30>

 T 321 a, T 162, earth; battery, relay 18 ', contactor f of the combiner S in position 3, T 326b, T 162, earth.

   Relay 62 (freeze 3) releases its armature at the end of the time allotted by its takeoff delay and prepares in R 621, R 622 and R 623 for reception of the third and fourth digits on the secondary translator.



   When the ch2 searcher wipers (fig 4) associated with the secondary translator have reached the level of the calling primary translator, the following circuit is completed: earth, T 923, rectifier Q 31, series windings of relay 91, wiper T2 of the finder Ch2 and bench contact, wire 981 through cable 98, (fig. 3), make contact D'n32, the two right windings in parallel with relay 64, battery.



   Relay, is 91 comes to bonding and opens in R 911 the advancement circuit of the searcher Ch2 which stops in the position considered.



   Note that the start-up wire 971 and the wire Seeker Ch2 stop 981 are in principle multiple on all secondary translators serving four digit combinations starting with the same first two digits. Thus, for example, if the relay D'n3 (fig. 3) corresponds to a code starting with 94, the wires 971 and 981 will be multiplied on all the secondary translators intended to receive the codes starting with one of the hundred combinations 9400 to 9499. Researchers associated with these secondary translators will sit simultaneously. on, but only the first seeker who will stop on the calling primary translator will serve, the call-.



   In T 911, the relay 91 completes the circuit of the relay 96, which comes to the bonding; in T 912, it short-circuits its high resistance winding to lower the test potential on the trot, eur T2, in T 913, it completes the circuit of relay Gl, which comes to the bonding.



   Relay 64 of the primary translator opens in R 641 the shoe shine

  <Desc / Clms Page number 31>

 relay 92, which takes off.



   Relay Gl (fig. 4) prepares for switching on one of the relays El to EO.



   The third and fourth digits of the code received are then recorded in the secondary translator through the following circuit: earth, generator Ge 1 (fig. 2b), R 312, windings of relay 29, rectifiers Q 15, Q 16 , Q 12 'to Q 15', contacts of the various retransmitting relays 17 to 20, T 593 ', T 594' and T 595 ', wipers I 11 to 1 13 and bench contacts, wires 768, 769, and 761' through cable 76, (fig. 3), T 731, T 731 ', T 734, R 621 to R 623, wires 988,989 and 981' through cable 98 (fig.

   4), bank and wiper contacts 121 to 123, T 965, T 966, T 965 'and relays 85 to 90, 94 and 95. Relays 85, 86, 87 and 94 are used for recording the 3rd digit, relays 88, 89, 90 and 95 for recording the 4th digit, according to the process indicated for the primary translator.



   Relay 29, in the recorder completes, as has been indicated, the circuit of the electro S which attracts its armature.



   To simplify the explanation, will assume that the marker relays 87 and 89 are glued. The El and Fl relays are then energized on the following circuits: battery, El relay, wire 991, through cable 99, work contact G 13, associated with relay Gl, R 862, R 942, T 872, R 852 , earth, for relay El, and, battery, relay FI, connection x'l, wire 1001 through cable 100, work contact E 14 associated with relay El, R 883, R 953, T 892, earth for relay Fl.



   If, as has already been assumed, the code received begins with 94, the ten relays E1 to EO will correspond respectively to the ten codes starting with 941 to 940. They each have ten working contacts, which gives a total of one hundred contacts, corresponding respectively to the one hundred codes starting with the combinations 9400 to 9499. As indicated for the translator

  <Desc / Clms Page number 32>

 primary, these 100 codes will not generally give rise to 100 different routes, two or more codes may correspond to the same route.

   A certain number of relays are therefore provided, such as Fl to Fn, the number of which is generally less than 100 and each corresponding to a determined routing, the same relay Fl being able to be, by appropriate connections x'l, x'2 , connected to several of the contacts of relays El to EO.



   The mechanism for retransmission of the different combinations by the secondary translator is identical to that indicated for the primary translator. The combination used for the interior selections is transmitted on the following circuit: generator Ge3, transformer TR3, rectifiers Q33 to Q 36, appropriate connections such as y ', cable 101, make contacts F 13 to F 16 of relay Fl, T 962 'and T 963', wipers 0 24 and 0 25 from researcher Ch2, wires 988 and 986 through cable 98, (fig. 3), T 732 'and T 733', wires 764 and 765 through the cable 76 (freezes 2a) - bench and wiper contacts 0 14 and 0 15, T 594 and T 595, relays 49, 50, 51, 52, 53; 54,57 and 57 ', earth.



   The combination used for the external selections is transmitted on the following circuit: generator Ge3 (fig. 4), transformer TR3, rectifiers Q 33 to Q 36, connection such as v ', Cable 102, work contacts F 17 to F 19, T 962, T 963 and T 964, wipers 0 21 to 0 23, wires 982 to, 984 through cable 98 (fig. 3) T 732, T 733, T 735, wires 761 to 763 through cable 76, (fig. 2a) bench and wiper contacts 011 to 013, T 591 to T 593, relays 41 to 48, earth.



   The combination relating to the tariff is transmitted on the following circuit generator Ge3, transformer TR3, rectifiers Q 33 to Q 36, appropriate connection such as z ', cable 103, working contacts F 11 and F 12 of relay Fl, T 964' , Cr2 wiper and bank contact, wire 987 through wire 98, T 735 ', wire 767 through wire 76, bank contact and wiper CRl, T 592', wire 746 and

  <Desc / Clms Page number 33>

 selector Se associated with the recorder.



   The primary translator is then released as in the general case, opening at D'n31 the circuit of relay 91 of the secondary translator. All the relays of said translator then return to idle. The various operations continue in the recorder as indicated in the general case.



   If, for one reason or another, the various selections are prolonged beyond a predetermined period, it may be advantageous to provide a device which releases the recorder to avoid indefinitely blocking organs which may be. used for establishing another call. However, the time required to make said selections depends on several factors, including the number of transit exchanges through which the call must be routed. It is therefore logical that the length of time allowed for the various selections depends on the first digits of the code received.



   If, for a given call sign, this duration must be 16 seconds, the primary translator sends to the TE1 wiper (fig. 2a), a pulsed current in a negative direction, which causes the relays 56 and 58 to stick by the TE1 wiper, T 591 ', rectifier Q 11, left winding 56, inner winding 58, rectifier Q 14, earth.



   After reception by the recorder of the translated combination, the relay 12 sticks to the marker relay holding circuit; as has been indicated, and the following circuit is completed: earth, Ca 12 cam, R 351, T 122, T rotation electro, battery. Said electro moves the rubbers of the switch corresponding to the rate of the cam Ca 12, which will be assumed to be two revolutions per second.



   After six seconds, the switch T has taken three steps, and the relay 58 'is energized through the wiper a of the switch T in position 3, and is maintained by T 581'. 'We will assume that

  <Desc / Clms Page number 34>

 At this time the selector Se, whose stop circuit normally passes the wire 841, has not finished searching, because the circuits of the normal channel are congested. If there is a free circuit in the emergency channel, the selector will be able to orient itself on said circuit, the stop relay 22 energizing by, r wire 742 ', windings in series of 22, rectifier Q 17, T 232, wiper a of the combiner S in position 4, T 492, T 502, R 512, R 523, R 601 ', connection in dotted line a, T 585', rectifier Qll ', connection b, wire 842, cable 84 .



   It will be noted that the presence of the rectifier Q 11 'is essential in the event that several normal channels use the same diverted channel. If the normal channels corresponding to the control wires 841 and 843 use the same diverted channel corresponding to the control wire 842, for example, connect the control wires 843 and 842 by a working contact of the relay 58 'and connections such as c and d.

   If the code received corresponds to the activation of wire 841, and if the rectifiers Q 11 'and Q 12' did not exist, the following circuit could be completed: wire 742 ', windings in series of 22, rectifier Q 17, T 232, wiper a. of combiner S in position 4, T 492, T 502, R 512, R 523, R 601 ', connection a, T 586', connection b, connection d, T 584 ', connection c, wire 843, which could cause untimely stopping of the selector on the circuit corresponding to control wire 843 -
If the recorder has not yet finished its function when the switch T reaches position 8, the following circuit is completed: battery, lower winding 33 ', wiper a of switch T in position 8, T 582, T 562, R 552, earth.

   The relay 33 'comes to sticking and causes in T 331' the placing of a battery on the wire 741, through the resistor Re 11a, which causes the release of the local exchange, and the return of the caller busy. Earth is then removed on wire 742, relay 16 takes off and the recorder then releases as indicated.

  <Desc / Clms Page number 35>

 



   When the various selections are completed and the return pulse is received, contact R 351 is opened and the timing device is switched off.



   It may happen that the recorder is in the position to retransmit any digit before that digit is completely recorded. If, for example, the recorder is in the 7th digit retransmission position, the S combiner is in position 9, and if the digit is being recorded, the A combiner is in position 7. The following circuit is then completed: battery, relay 31, contactor e of combiner A in position 7; wiper i of combiner S in position 9, mgl wire, T 162, earth. Relay 31 sticks and opens in R 311 the circuit of relays 37 and 37. ' that take off. Relay 27, having its circuit open at T 371, will no longer be able to re-energize when the Call cam passes and prevents any retransmission of digits at T 271 and T 272.



   If the third or fourth digit is not fully recorded when the secondary translator is in the position to receive them, relay 31 is energized by the contactor e of combiner A in position 3 or 4, T 281 and the wiper i of the combiner S in position 3, making it impossible to send any combination to the secondary translator due to the opening of its contact R 312.



   In general, it has been indicated that the same secondary translator could serve 100 different combinations starting with the same two first digits, the combinations 9400 to 9499, for example. In the diagram shown, the secondary translator also serves 100 distinct combinations of the first ones, starting with the same first two digits (9500 to 9599, for example). If the first two digits received correspond to the energization of relay Dn'3 (fig. 3), relay 91 (fig. 4) sticks as indicated, which causes relay Gl to operate. and one of the relays El to EO.

   If on the other hand the two

  <Desc / Clms Page number 36>

 first digits received correspond to the energization of relay Dn'4 (freeze 3), the stop circuit of the researcher Ch2 is as follows: earth, T 924, rectifier Q 32, winding in series of 93, trotter T2 and contact bench, wire 981 through cable 98 (pin 1), contact Dn'41 associated with relay Dn'4, the two left windings of relay 64, special battery Bt2, earth. Relay 93 causes T 933 to operate relay G2, which in turn prepares the circuit of one of the ten relays E'1 to E'O. These last relays each have ten contacts, which makes 100 contacts for the ten relays, corresponding to 100 codes 9500 to 9599 respectively.



   We will now describe, with reference to Figures 5a, 5b and 6, the operation of a recorder and a translator for incoming exchange.



   When the recorder, shown in fig. 5a and 5b, and the translator, shown in figure 6, are available, all the relays (except 190,) are at rest, and the switch S 'in position 0. It will be assumed that the researcher Ch3, associated with the recorder, is normally oriented towards a free translator. A battery is then put on wire 1871, (fig. 5a) through the following circuit: wire 1871, R 1291 ', wiper of switch S' in position 0, wiper T3 of researcher Ch3 and bench contact , wire 1882 through cable 188, (pin 6), R 1791 ', resistor Re 51, battery, which indicates to the selector Se' associated with the recorder that said recorder is available and ready to be used for the 'routing a call.



   When receiving a call, a ground is put on the wires 1874 and 1875 by the selector Se 'associated with the recorder, which causes the excitation of the relay 116 on its two windings.



  In T 1161, said relay completes the following circuit: earth, T 1161 wiper P3 and bench contact 1'892, wire 1881, multiplied on bench contacts 1892 of all Ch3 researchers of the installation

  <Desc / Clms Page number 37>

 and, in the other recorders having their finder Ch3 stopped on the same azimuth, wire 1881, bench contact 1892, wiper P3, R 1161, R 1051, contact r3, associated with the electro of rotation R3, electro R3, contact of normally closed work, T 1901, battery.



  By the play of their contact r3, the R3 electros move the rubbers of the associated researchers to the next position. Said researchers stop at this position, but only if said position gives access to a translator who is not in the call position; otherwise, they take one more step following the previously indicated mechanism. Thus, any Ch3 seeker, upon receipt of a call, causes the advancement of all other similar seekers stopped on the same azimuth. We then understand why we could suppose that the researcher Ch3 was normally oriented towards a free translator.

   Of course, it would be useless to promote the advancement of researchers if all the translators to which they have access were occupied; a relay 190 is provided, which is normally at gluing, but de-energizes if all the translators are occupied, opening at T 1901 the advancement circuit of all the researchers.



   In T 1161, relay 116 has also completed the following circuit: earth, T 1161, wiper P3 and bank contact, wire 1881, (fig. 6) relay 179 'battery; in T 1162, it prepares the circuit of relay 130; T 1164, it completes the circuit of relay 129 through wire 1876 and a ground put by selector Se '.



   Relay 129 puts in T 1291 a general earth which will be used during operation, and completes the following circuit: earth, T 1291, contactor e of combiner S 'in position 0, relay 110' resistance Re 41, associated contact s' to the rotation electro S ', electro S'., 'battery. Due to the characteristics of relay 110 ′ and of electro S'- alone, relay 110 ′ energizes at the end of the time allotted by its sticking delay.

   In T 1292, relay 129 completes a holding circuit: in T 1293 and T 1294 ', it causes

  <Desc / Clms Page number 38>

 the emission of a signal back to the outgoing central through the following circuit: generator Grf, capacitors C41 and C42, T 1293 and T 1294 ', wipers b and c of combiner S' in position 0, transformer TR4, wires 1874 and 1875; T 1294 and T 1295 ', it prepares the maintenance of the various marker relays.



   Relay 109 is energized through contact 1101 '. In T 1092, and T 1094, it completes the following circuit: battery, electric S 'and its rotation contact s', T 1094, T 1092, T 1291, earth.



  The electro S 'maintains its bonding through resistor Re 42 and opens through its contact s' the circuit of relay 110 'which takes off, itself opening in T 1101' the circuit of relay 109, which in turn takes off . Relay 109 makes a cut in T 1092 on the circuit of electro S ', which releases its armature and moves its wipers to position 1.



   The signal back to the outgoing exchange ends, due to the advancement of the combiner S 'to position 1.



   Relay 130 is bonded by: battery, relay 130, wiper and combiner S 'in position 1, T 1162, earth, is maintained by T 1307 and connects, through its various work contacts, the recorder to the translator engaged.



   The sending of the signal back to the outgoing exchange caused on the part of said exchange first the cessation of the continuous signal which had been used to route the call through the various transit exchanges, then the retransmission of the call. Complete code of the requested subscriber, in the form of a mixture of several currents of different frequencies. It will be assumed that there are 4 frequencies fl, f2, f3, f4 for the transmission of the first digit, and four other frequencies f5 to f8 for the transmission of the second digit, these two digits being received simultaneously.



   The numbering reception circuit is as follows: wires 1872 and 1873, T 1301 and T 1302, wiper A3, B3 of the researcher Ch3 and bank contacts, wires 1883 and 1884 through cable 88,

  <Desc / Clms Page number 39>

 (freeze 6), detector De 5.



   Several of the contacts cfl to cf8 are actuated according to the frequencies received. If the frequency fl is received, the contact cfl is closed and causes the excitation of relay 157 on its right-hand winding through contact R 1801; if the frequency f2 is received, the contact cf2 is actuated and the relay 157 'is energized, and so on. It will only be noted that with regard to the frequencies f5 to f8, the relay 179 is energized in series with the marker relays.



   The following two tables give the correspondence between the frequencies received, the figures represented by said frequencies and the marker relays which come to the collage.
 EMI39.1
 
 <tb>



  1st <SEP> digit <SEP> Frequencies <SEP> Relay
 <tb>
 
 EMI39.2
 receive c ± rreµQ ± ngaLt ± s¯Ù excitedµ Ë2 # # -.- 29ÊSB2es¯ excited
 EMI39.3
 
 <tb> 1 <SEP> fl <SEP>: <SEP> 157
 <tb>
 <tb>
 <tb> 2 <SEP> f2 <SEP>: <SEP> 157 '
 <tb>
 <tb>
 <tb> 3 <SEP> f3 <SEP>: <SEP> 158
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP> f4 <SEP>: <SEP> 158 '
 <tb>
 <tb>
 <tb> 5 <SEP> fl <SEP> - <SEP> f2 <SEP>: <SEP> 157 <SEP> - <SEP> 157 '
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> fl <SEP> - <SEP> f3 <SEP>: <SEP> 157 <SEP> - <SEP> 158
 <tb>
 <tb>
 <tb> 7 <SEP> fl <SEP> - <SEP> f4 <SEP>: <SEP> 157 <SEP> - <SEP> 158 '
 <tb>
 <tb>
 <tb> 8 <SEP> f2 <SEP> - <SEP> f3 <SEP>: <SEP> 157'-158
 <tb>
 <tb>
 <tb>
 <tb> 9 <SEP> f2 <SEP> - <SEP> f4 <SEP>: <SEP> 157'-158 '
 <tb>
 <tb>
 <tb> 0 <SEP> f3 <SEP>, - <SEP> f4 <SEP>: <SEP> 158 <SEP> - <SEP> 158 '
 <tb>
 

  <Desc / Clms Page number 40>

 
 EMI40.1
 
 <tb> 2nd <SEP> digit <SEP>:

    <SEP> Frequencies <SEP> Relay
 <tb>
 <tb> received Corresponding <SEP> <SEP> excited
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP> f5 <SEP>: <SEP> 159
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP> f6 <SEP>: <SEP> 159 '
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP> f7 <SEP>: <SEP> 160
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP> f8 <SEP>: <SEP> 160 '
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP> f5 <SEP> - <SEP> f6 <SEP> 159 <SEP> - <SEP> 159 '
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> f5 <SEP> - <SEP> f7 <SEP> 159 <SEP> - <SEP> 160
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP> f5 <SEP> - <SEP> f8 <SEP>: <SEP> 159 <SEP> - <SEP> 160 '
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP> f6 <SEP> - <SEP> f7 <SEP>: <SEP> 159'- <SEP> 160
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 9 <SEP> f6 <SEP> - <SEP> f8 <SEP>: <SEP> 159'- <SEP> 160 '
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> f7 <SEP> - <SEP> f8 <SEP>:

    <SEP> 160 <SEP> - <SEP> 160 '
 <tb>
 
Relay 157, if it has been energized, is maintained by: battery, series windings of 157, T 1571, T 1792 ', earth.



  The relays 157 ', 158, 158', 159, 159 ', 160,160' complete the analog holding circuits.



   The relays 157,157 ', 158,158', which were used to register the first digit, complete, by their different contacts and connections such as 1911, 1913, 1915, the circuit of the left coil of one of the relays K1 to K3; the relays 159, 159 ': 160, 160' which received the second digit complete, through connections such as 1912, 1914, 1916, the circuit of the right coil of relays K1 to K3. These latter relays only attract their armature if the circuits of their two coils are completed.



   The reception of the first two digits, or Il precombination "therefore results in the final excitation of one of the relays K1 to K3. It would seem, at first glance, that it would be necessary to foresee auta, nt of relays analogous to, K1 that there are pre-combinations, that is to say 100. But, when the call has been routed to the translator of fig. 6, that is to say to the attachment zone of the requested,

  <Desc / Clms Page number 41>

 the number of pre-combinations to be served is very low and in practice will never exceed two or three. This amounts to saying that if a 2-digit pre-combination corresponds, for example, to a French department, a transit zone will never serve more than two or three departments.



   It will be assumed, in the example shown, that the marker relays 157 ′ and 159 were respectively energized when the first and second digits were received, which, according to the preceding tables, corresponds to the pre-combination "21". ; relay Kl attracts its armature, the following two circuits being completed: battery, winding of the left coil of relay Kl, appropriate connection such as 1911, R 1583 ', R 1583, T 1572', R 1572, earth and battery, right coil winding of relay Kl, connection 1912, R 1604 ', R 1604, R 1593', T 1592, earth. It will be noted that the left coil of relay K2 is energized in parallel with that of relay K1, through connection 1913, but said relay remains at rest, the circuit of its right coil not being completed.

   The relay Kl prepares by its contacts Kll, K 12 and following the circuit of one of the relays Jl to Jn.



   Relay 179 has energized in series with the different marker relays, as indicated. In T 1791, it completes the following circuit: battery, relay 185, R 1805, T 1791, T 1792 ', earth.



   The relay 185 prepares, in T 1851, the circuit of the relay 180 currently short-circuited by the earth which caused the excitation of 185 and the earth put by T 1792 '.



   At the end of the reception of the first two digits, the contacts cfl to cf8 are opened and the relay 179 takes off, removing in T 1791 the earth which short-circuited the relay 180. This last relay is energized, and relay 185 is maintained on the following circuit: battery, relay 185 and 180 in series, T 1851, T 1792 ', earth. Relay 180, through its contacts RT 1801 to RT 1808, isolates relays 157 to

  <Desc / Clms Page number 42>

 160 'and prepare the circuit for relays 167 to 170', which will be used to register the 3rd and 4th digits; at T 1805, it prepares the circuit for relays 186 and '185'.



   The 3rd and 4th digits are received on relays 167 to 170 '. If we receive the. frequency f1, relay 167 is energized by battery, right winding of 167, R 1861, T 1801, conta, and, cfl, earth; if the frequency f2 is received, relay 167 'is energized and so on.



   Relays 167,167 ', 168,168', which have recorded the 3rd digit, cause, by their different contacts, the excitation of one of the ten relays H1 to H10. Relays 169, 169 ', 170, 170', which recorded the 4th digit, ground one of the ten wires 1921 to 1920 through cable 192. Finally, one of the relays Jl to. Jn is energized through one of the make contacts of one of the relays K1 to, K3, a suitable connection such as 1941 to 1943, wire 193, one of the work contacts of the rela, is Hl to H10, cable 192, the various contacts of the 3rd digit recording relays, earth.



   The first four digits received are therefore translated ultimately by the excitation of one of the relays Jl to. Jn. It would appear at first glance that a same "pre-combination", or combination of the first two digits can be associated with 100 different combinations of the 3rd and 4th digits, and that each relay such as K1 should have 100 different contacts. In practice, the number of combinations to be translated, for the same "pre-combination, ison", is always less than 100, eb it will not be necessary to provide 100 contacts on relays K1 to K3. If, however, the number of contacts is too high, nothing prevents the said relays from being doubled by other auxiliary relays.



   It will be assumed, by way of example, that the relay Jl has come to bonding.



   The different translated combinations are sent by the

  <Desc / Clms Page number 43>

 translator on the recorder, in the form of pulsed currents of varying direction and intensity. These currents are produced from the Ge5 generator (fig. 6) and from the TR5 transformer; their direction is determined by one or more of the rectifiers Q 51 'to Q 54, their intensity is a function of one of the taps 1892 or 1893 made on the secondary of the transformer TR5.



   The first circuit on which the first translated combination is transmitted is: generator Ge5, transformers TR5, one of taps 1892 or 1893, one of rectifiers Q51 to Q54, 'one of six wires 1951 to 1956, suitable connection such as 1961, wire 1971, through wire 197, make contact Jll associated with relay Jl, wire 1885 through wire 188, (fig. 5a), bench contact and wiper 031 , T 1303, rectifier Q 42, right winding of 148, rectifier Q 44, relay 146, earth, for positive alternations and, for negative alternations, rectifier Q41, right winding of 148, rectifier Q43, relay 147, Earth.



  Relay 147 is energized for currents in the negative direction (by conventionally taking the direction of the currents going from the translator to the recorder as the positive direction, the relay 146 is energized for the currents in the positive direction, the relay 148 works only for currents whose intensity reaches a determined value, which occurs when using the 1892 socket.



   The second circuit on which the first translated combination is transmitted is: generator Ge 5 (fig. 6), transformer TR5, socket 1892, one of the rectifiers Q51 or Q52, one of the three wires 1951 to 1953, connection suitable as 1962, wire 1972 through wire 197, 'make contact J 12 associated with relay J1, wire 1886 through wire 188, (fig. 5a) make contact and wiper '0 32, T 1304, rectifier Q 45, relay 149, earth. The relay 149 comes or not to sticking depending on whether the current received is in a negative or positive direction.



   The following table gives the correspondence between the

  <Desc / Clms Page number 44>

 polarities returned by the translator, the translated digits represented by said polarities, and the relays energized. The different signs used have the same meaning as in the previous tables.
 EMI44.1
 
 <tb>



  Figure <SEP> Polarities <SEP> bets <SEP> Relay <SEP> excited
 <tb>
 <tb> translated <SEP> on <SEP> trotters¯¯¯¯¯¯
 <tb>
 <tb>
 <tb>
 <tb>: <SEP> 0 <SEP> 31 <SEP>: <SEP> 0 <SEP> 32 <SEP>:
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP> ¯ <SEP> R <SEP> 146
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP> - <SEP> R <SEP> 147
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP> Alt <SEP>: <SEP> 146 <SEP> 147 <SEP> 148 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP>: <SEP>: <SEP> - <SEP>: <SEP> 149
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP> Alt <SEP> R <SEP>: <SEP> 146 <SEP> 147
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP> ¯ <SEP>: <SEP>: <SEP> 146 <SEP> 148
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP> ¯ <SEP> R <SEP>: <SEP> 146 <SEP> 149
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP>: <SEP> - <SEP>: <SEP>:

    <SEP> 147 <SEP> 148
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> - <SEP> R <SEP>: <SEP> 147 <SEP> 149
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> Ait <SEP>: <SEP> 146 <SEP> 147 <SEP> 148 <SEP> 149
 <tb>
 
The second translated combination is sent to the recorder according to a mechanism similar to the previous one, but this time using wipers 032 and 033 and relays 104 a to 104 d.



  It will only be noted that the wiper 32 is common to the transmission circuits of the first two translated combinations. If it receives negative alternations, it is relay 149 relating to the. 1st translated combination that gets excited; if it receives positive alternations, - 'is relay 104 d relating to the 2nd combination which is operating. We could therefore establish a correspondence scale analogous to the previous one, but by replacing in the column relating to the trotter 032 the sign - by the sign ¯. If relays 149 and 104 d must be simultaneously energized, the driver returns to the wiper. 032 both positive and negative half-waves.

  <Desc / Clms Page number 45>

 



   The third translated combination is sent to the recorder in the same way using the wipers 034.035 and the relays 106a to 106d; the fourth translated combination is received through wipers 035,036 or relays 108a to 108d.



   The relay 105 is energized in parallel on one or more of the relays 146, 147 and 149 through the wipers of the combiner S 'in position 1.



   Relay 147, if it has energized, is completed by the following holding circuit: earth, relay'147, T 1471, T 1294, battery, relay 146, if it has energized, is maintained by: earth , relay 146, T 1461, T 1295 ', special battery Bt2, earth. The other marker relays are maintained in a similar fashion. It will be noted that the poles placed on the contacts T 1294 and T 1295 ′ are such that the current used for maintaining each relay is in the same direction as the excitation current, in order to avoid untimely taking off of said relay.



   Relay 105 completes the following circuit in T 1052: electro battery S 'and its rotation contact s', contactor e of the combiner S' in position 1, T 1052, T 1291, earth; in T 1053 and T 1054, it prepares the sending of the tap signal to the central units placed downstream in T 1055, a holding circuit is completed through the general contact earth T 1291.



   The electro S ', by the play of its contact s', advances the friction switches of the associated combiner in position 2. The relay 110 ′ is then short-circuited by the wiper c of said combiner.



   In position 2, relay 136 is energized by battery, lower winding of 136, wiper a of combiner S 'in position 2, wire 204, T 1291, earth.



   Relay 136 puts an earth on wire 1873 'by T 1364, R 1371, R 1351, wiper a of the combiner S' in position 2, T 1291, earth, which activates the selector associated with the recorder considered.

  <Desc / Clms Page number 46>

 



   The level, u on which said selector must be oriented is determined by the situation of relays 146 to 149 which have registered the 1st translated combination. If, for example the relays 146, 147, eb 148 are glued, which corresponds to the number "3", the selector will stop on one of the positions connected to the wire 1983 through, through the cable 198. In fact, when this position is reached, the following circuit is completed, earth on the 1983 wire, put by the selector through the cable 198, T 1482, T 1474, T 1463, R 1492, trotter b of the combiner S 'in position 2, T 1362, rectifier Q 46, windings in series of relay 135, wire 1874 'and battery set by the selector when it arrives on a free line located in the desired level.



   Relay 135 comes to sticking; in R 1351, it opens the advance circuit of the selector, which stops in the position considered; at T 1352, it places the upper winding of relay 136 in parallel with its lower winding, in order to lower the test potential.



   The relay 136 takes off, due to the fact that its two windings produce equal flows and of opposite sign, ire.En R 1.361 ,. it places an earth on wire 1871 'by R 1361, T 1351, wiper a of the combiner S' in position 2, T 1291, earth, in order to cause, in the selector, the excitation of a relay which will complete the circuit of the line wires.



   When this operation is carried out, the selector causes the earthing of wires 1874 'and 1871'. The relay 135, short-circuited, takes off, and the relay 136 is re-energized due to the disappearance of the flux of its opposing winding. Relay 136 completes at T 1361 the circuit of the right winding of relay 118 through the earth put on wire 1871 'by the selector.



   The relay 118 prepares, in T 1181 and T 1183, the sending of appropriate polarities on the wires 1877 and 1878, which will be used

  <Desc / Clms Page number 47>

 later for orientation of local selectors; in T 1182, it prepares the circuit of retransmitting relays 150, 150 ', 155, 155'; in T 1184, a maintenance circuit is completed by: earth, T 1291, wire 204, left winding of 118, T 1184, resistance Re 43 and Re 44 in parallel, wires 1879 and 1870, and earth put by the selector ; in T 1185, it causes the advance to position 3 of the combiner S 'on the following circuit: battery, electro S' and its de-rotation contact s '., wiper c of the combiner S' in position 2, T 1.185, earth.



   Due to the advancement of combiner S 'to position 3, relay 136 takes off and relays 145, 139, 138 and 140 move into a position corresponding to the second digit translated. If we assume, by way of example, that this number is a 5, which corresponds to the energization of relays 104 a and 104 b and at rest of relays 104 this 104 d, relays 139 and 138 s' energize respectively on the following circuits: earth, relay 139, wiper b of combiner S 'in position 3, T 1042 b, resistor Re 45, T 1294, battery, and earth, relay 138, wiper a of combiner S 'in position 3, T 1041 a, resistor Re 46, T 1295', positive pole of the special battery Bt2, earth.



   The relays 150, 150 ', 155,155' are then put in a position corresponding to that of the relays 138,139, 140 and 145.



  If, as we have assumed, the relays 138 and 139 are glued, the relays 150 and 150 'are energized on the following circuits: battery, relay 150, T 1381, R 1401, R 1091', earth and battery, relay 150 ', T 1391, R 1401, R 1091', earth. An alternating current is then sent on wire 1878, through the following circuit, in order to control the orientation of the local selection stages, other than the first: generator Ge 41 ', rectifiers Q 47 and Q 48, windings of relay 107 , T 1501 and T 1501 ', high resistance Re 47, T 1181, wire 1878.



   The following table gives the correspondence between the

  <Desc / Clms Page number 48>

 different figures translated, relays energized and polarities emitted on wires 1877 and 1878:
 EMI48.1
 
 <tb> 2nd <SEP> Relay <SEP> saved <SEP>: Relay <SEP> retrans- <SEP>: <SEP> Polarities <SEP> re-
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> number: <SEP> treurs <SEP> excited <SEP>: directors <SEP> excited <SEP>: <SEP> transmitted.¯¯¯¯
 <tb> translated: <SEP>: <SEP> Wire <SEP> 1877 <SEP> Wire <SEP> 1878 <SEP>
 <tb>: <SEP>: <SEP>: <SEP>: <SEP>:
 <tb>
 <tb> 1 <SEP>: 104a <SEP>: 138 <SEP>: 150 <SEP>: <SEP>: <SEP> ¯ <SEP> R
 <tb>
 <tb>: <SEP>: <SEP>: <SEP>: <SEP>:
 <tb>
 <tb> 2 <SEP>: 104b <SEP>: 139 <SEP>: 150 ' <SEP>: <SEP>: <SEP> - <SEP> R
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP>: 104a-104b-104c <SEP>: 138-139 <SEP>: 150 <SEP> -150 ':

    <SEP> Alt
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>: <SEP>: 140 <SEP>: 155 <SEP>: <SEP>:
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP>: 104d <SEP>: 145 <SEP>: 155 ' <SEP> Alt <SEP> Alt <SEP> R
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP>: 104a-104b <SEP>: 138-139 <SEP>: 150 <SEP> -150 ': <SEP> Alt <SEP> R
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP>: 104a-104c <SEP>: 138-140 <SEP>: 150 <SEP> -155
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP>: 104a-104d <SEP>: 138-145 <SEP>: 150 <SEP> -155 ': <SEP> Alt <SEP> ¯ <SEP> R
 <tb>
 <tb>
 <tb> 8 <SEP>: 104b-104c <SEP>: 139-140 <SEP>: 150'-155 <SEP>: <SEP>
 <tb>
 <tb>
 <tb> 9 <SEP>: 104b-104d <SEP>: 139-145 <SEP>: 150'-155 ': <SEP> Alt <SEP> - <SEP> R
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP> 104a-104b-104c-104d <SEP>: 138-139 <SEP>: 150 <SEP> -150 ' <SEP>:

    <SEP> Alt <SEP> Alt
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>: 140-145 <SEP>: 155 <SEP> -155 '
 <tb>
 
The relay 107 is energized in the circuit for transmitting the control polarity. It completes, in T 1071 the circuit of relay 109, and in T 1072, a holding circuit for the retransmitter relays 150, 150 ', 155, 155'
Relay 109 completes the following circuit at T 1092 and T 1094: battery, electro S 'and its rotation contact s', T 1094, T 1092, T 1291, earth. The electro S 'attracts its armature and is maintained through the resistance Re 42.



   When the selection signal has been registered in the appropriate organ, a cut is made on wire 1878 and relay 107 takes off, opening at T 1071 the circuit of relay 109 which in turn takes off, and T 1092 the circuit. electro S '. The latter releases its frame and moves the rubbers of the a.ssoiced combiner to position 4, thus preparing to send the translated combination.

  <Desc / Clms Page number 49>

 next. The relays 138, 139, 140, 145 as well as the relays 150, 150 ', 155, 155' are put in a position corresponding to the 3rd translated combination.



   It will be assumed that the considered exchange is only a transit center, and that an outgoing circuit is reached after the second selection. Earth is then removed by the selector on wires 1879 and 1870 and relay 118 takes off.



   The recorder then emits a tap signal and a selection signal superimposed on the following circuits: generator Gfp, resistors Re 41 'and Re 42', T 1053 and T 1054, transformer TR'4, R 1183 and R 1181, wire 1877 and 1878, for the tap signal, generator Gfl to Gf4, resistors Re 43 'to Re 40', T 1502, T 1503, T 1502 ', T 1503', T 1551, 1552, T 1551 ', T 1552' , transformer TR'4 and the previous circuit for the selection signals, depending on the respective position occupied by the relays 150, 150 ', 155, 155'.



  The following table gives the correspondence between the energized relays and the frequencies sent.
 EMI49.1
 
 <tb>



  3rd <SEP> digit: <SEP> Relay <SEP> saved <SEP>: <SEP> Relay <SEP> retransmit <SEP> Frequencies
 <tb>
 <tb>
 <tb> translated <SEP> treurs <SEP> excited <SEP>: <SEP> teurs <SEP> excited. <SEP> issued
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 1 <SEP>: <SEP> 106 <SEP> a <SEP>: 138 <SEP>: 150 <SEP> f1
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 2 <SEP>: <SEP> 106 <SEP> b <SEP>: 139 <SEP>: 150 ' <SEP> f2
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 3 <SEP>: <SEP> 106a, <SEP> b, <SEP> c <SEP>: 138-139-140: 155 <SEP> f3
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 4 <SEP>: <SEP> 106d <SEP>: 145 <SEP>: 155 ' <SEP> f4
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 5 <SEP>: <SEP> 106a <SEP> and <SEP> b <SEP>: 138-139 <SEP>: 150-150 ' <SEP> fl <SEP> - <SEP> f2
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 6 <SEP>:

    <SEP> 106a <SEP> and <SEP> c <SEP>: 138-140 <SEP>: 150-155 <SEP> fl <SEP> - <SEP> f3
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 7 <SEP> 106a <SEP> and <SEP> d <SEP>: 138-145 <SEP>: 150-155 ' <SEP> fl <SEP> - <SEP> f4 <SEP>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 8 <SEP>: <SEP> 106b <SEP> and <SEP> c <SEP>: 139-140 <SEP>: 150'-155 <SEP> f2 <SEP> - <SEP> f3
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 9 <SEP>: <SEP> 106b <SEP> and <SEP> d <SEP>: 139-145 <SEP>: 150'-155 ' <SEP>. <SEP> f2 <SEP> - <SEP> f4
 <tb>
 <tb>
 <tb>
 <tb>
 <tb>
 <tb> 0 <SEP>: <SEP> 106a, <SEP> b, <SEP> c <SEP> and <SEP> d <SEP>: 138-139-140: 155 <SEP> -155 ' <SEP> f3 <SEP> - <SEP> f4
 <tb>
 <tb>
 <tb>:

    <SEP> 145
 <tb>
 

  <Desc / Clms Page number 50>

 
It will be noted that, due to the opening of contact T 1182, the relays 150, 150 ', 155, 155' do not operate in the same way as in the case of local selections, thus, for the number "O" the relays 155 and 155 'come only to the pasting, while in the case of local selections the four relays 150, 150', 155, 155 'worked, this in order to keep the same code as} Day the reception of the digits in the translator.



   The seizure signal occupies the first transit exchange located downstream from the office in question; the selection signal causes the orientation of the selector or selectors of said desk.



   When this orientation is completed, the transit exchange sends a return signal which is received on the following circuit: wires 1879 and 1870, transformer TR "4 and, detector DE4. Contact DE41 is actuated and relay 109 comes to the bonding, completing the circuit of the electro S 'through T 1094, T 1092, T 1291 and that of relay 109' through T 1091. The relay 109 'opens in R 1091' the circuit of relays 150,150 ', 155 and 155 'taking off The transmission of the selection signal ends.



   The transit office, no longer receiving a selection signal, terminates the transmission of the return signal; the relay 109 takes off, opening in T 1092 the holding circuit of the electro S 'which releases its armature and causes the wipers of the associated combiner to advance to position 5; relay 109 'having its circuit open in T 1091 takes off and prepares in R 1091' the relay circuit, is 150, 150 ', 155, 155'.



   The following translated combination is issued using the same process.



   While the recorder sends back the various translated combinations, either to the local selectors or to the remote offices, the reception of the called party code continues in the translator.



   After receiving the 3rd and 4th digits, conta, cts cf1 to cf8 (fig. 6) are opened and relay 179 takes off. Relay

  <Desc / Clms Page number 51>

 186, short-circuited in T 1791, gets excited, and relay 185 'is maintained in the following circuit: battery, relay 185' and 186, T 1851 ', T 1792', earth. Due to the energization of relay 186, the seme and 6th digits are simultaneously received on relays 175, 175 ', 176, 176', 177,177 ', 178, 178'. If one receives for example the frequency fl, the relay 175 is energized by battery, relay 175, T 1861, T 1801, contact cfl, earth, the other relays operating in a similar way.



   The relays 175, 178 'then cause, by their various contacts, the retransmission of the 5th and 6th digits on the recorder, following the process which has been indicated for the transmission of the translated combinations. This retransmission is made by: earth, generator Ge'5, rectifiers Q 55 to Q 58, the various working contacts of relays 175 to 178 ', wires 1881' to 1883 'through cable 188, (fig. 5a ), wipers 0 37 to 0 39, T 1304 'to T 1306', R 1282 to R 1284 and relays 110a to 110d, 115a to 115d.



   . The translator's relay 179 completes the following circuit in T 1792: earth, T 1792 ', T 1791, T 1805, T 1865, T 1792, wire 1884' through cable 188, (fig. 5 b), bench contact and wiper L, T 1306, R 1281, relay 128 ', battery.



   When the reception of the 5th and 6th digits is completed, the relay 179 takes off, as well as the relays 175 to 178 ', which have no hold circuit. The polarities emitted by the Ge'5 generator disappear, but the marker relays 110a to 110d, 115a to 115d remain as indicated.



   Relay 128 energizes and relay 128 'stays in the following circuit: battery, relay 128 to 128' in series, T 1281 ', wire 204, T 1291, earth. Relay 128 prepares, in T 1281, the switching on of relays 120 and 120 'and in T 1282, T 1283, T 1284 the retransmission of the 7th and 8th digits from the translator to the recorder. When the return signal, which follows the transmission of the translated 4th digit, ends, relay 109 takes off opening at T 1092

  <Desc / Clms Page number 52>

 the combiner circuit S which advances to position 6. The retransmitting relays 138, 139, 140, 145 and 150,150 ', 155,155' are then placed in a position corresponding to the 5th digit received. which is then retransmitted following the process indicated for the translated combinations.



   It will only be noted that, unlike what happened for the first four digits, the 5th and following digits are retransmitted without translation. In fact, if we examine FIG. 6, we notice that the first four digits translate definitively by the excitation of one of the relays Jl to Jn and that the polari- ties retransmitted through the contacts of each of these relays from the generator Ge5 depend on arbitrary connections such as 1961, 1962 --- etc. On the other hand, the 5th digit is received on relays 175,175 ', 176, 176', and the polarities retransmitted from the generator Ge'5 do not depend in any way on arbitrary connections, but are a function only of the position occupied by the relay 175,175 ', 176, 176'.

   If, for example, the 5th digit is a 1, the received frequency is fl, according to the code adopted in the previous tables. Relay 175 energizes and causes the transmission of positive halfwaves through a high resistance on the following circuit: generator Ge'5, rectifier Q56, T 752, resistor Re 52, wire 1881 ', through the cable 188, (pin 5a), bank contact 037, T 1304 ', R 1282, rectifiers 49, right winding 110c, rectifier Q 40, relay 110 a, earth.



  Relay 110a is energized on its own, causing relay 138 to be energized, which in turn causes relay 150 to be energized. Frequency fl is retransmitted as it has, had been received by T 1502 and T 1503 By examining the different circuits, we would also see that all the other frequencies corresponding to the digits 2 to 0 are retransmitted without translation.



   The 6th digit received is retransmitted without translation on position 7 of the combiner S.

  <Desc / Clms Page number 53>

 



   Note that the 5th and 6th digits were received simultaneously by the translator, and retransmitted in the same way on the recorder, but that they are sent to the remote exchanges one after the other, one after the other. on position 6 and the other on position 7 of the S combiner.



  * The 7th and 8th are also received in the translator under the relays 175 to 178 'and retransmitted as polarities to the recorder, as indicated for the 5th and 6th digits, but, due to the energization of relay 128 (fig. 5a), and of the closing of contacts T 1282 to T 1284, recording is done on relays 117a to 117d, for the 7th digit and 119a to 119d for the last digit. The retransmission is carried out following the process already indicated.



   The operations relating to the recording and the retransmission of the various digits are carried out simultaneously, although they have been described one after the other for the sake of clarity. But if the digits are received two by two, they are retransmitted one by one, so that, in practice, the reception will often end some time before the retransmission.



  Under these conditions, it is useless to keep the translator engaged, who no longer has any role to play when all the digits have been recorded.



   When the outgoing exchange transmits the call sign, the earth disappears on wires 1874 and 1875, and relay 116 takes off. In T 1161, it opens the circuit of the relay 179 'of the translator, which in turn takes off and causes the drop of all the relays in FIG. 6; at T 1162, it opens the circuit of relay 130, which, through its various contacts, disconnects the translator from the recorder.



   The translator is completely released and ready to be used for routing another call, while the recorder continues to transmit, if necessary, the various selection signals it has received from the translator.

  <Desc / Clms Page number 54>

 



   When this retransmission is finished, the combiner S arrives in position 10.



   Relay 136 is re-energized by battery, lower winding 136, combiner a of combiner S 'in position 10, wire 204, T 1291, earth. At T 1361, it causes relay 118 to re-energize by: battery, right winding of 118, T 1361, wire 1871 'and earth through selector Se'.



   An earth is then placed on the wire 1876 by the contact T 1185, trotter d of the combiner S 'in position 10, and T 1292, in order to cause the disconnection of the selector Se' and of the recorder.



  Relay 129 is maintained in parallel with the previous circuit.



   When this disconnection is made, the selector removes all polarity on the various wires which connect it to the recorder, which causes the relay 118 to take off. Relay 129 takes off, having its hold circuit open at T 1185, and causes all other relays to drop. The combiner S 'returns to rest on the following circuit: battery, electro S' and its rotation contact s ', wiper f of combiner S' in positions 1 to, 10, R 1291, earth.



   After having explained the general operation of the end recorder and translator, we will now deal with the various special cases which are liable to occur during operation.



   The recorder receives four translated combinations from the translator. It was assumed that the first was used for the orientation of the selector Se 'associated with the recorder, the second for the orientation of a second local selection stage and the last two for the orientation of the selectors. in remote offices. But, in fact, the last three translated combinations can be used for both local and external selections. Indeed, relay 118, as was indicated in the description of the general case, takes off at

  <Desc / Clms Page number 55>

 when the selections are completed in the office in question.



  Before this instant, the signals are sent in the form of polarity, by the Ge generator 41, through the contacts T 1181 and T 1183, so as to control the local selections; then the signals are emitted as a mixture of frequencies through the contacts R 1181 to R 1183 and control the external selections.



   It was assumed that the translator sent 4 translated combinations to the recorder. Practically, these 4 combinations are not always necessary, and there may be cases where the number of these combinations can be reduced to 3.2, 1 or even 0.



  We will deal with the case where the 4th translated combination must be deleted. Connections such as 1961, 1962 (fig. 6) are made such that no polarity capable of energizing relays 108a to 108d is placed on wires 1889 and 1880.



   When the combiner S 'arrives in position 5, the relays 138, 139, 140 and 145 do not find any excitation circuit, since the work contacts of the relays 108a to 108d are open.



  Those which were excited on position 4 of combiner S 'take off, causing relays 150,150', 155, 155 'to fall.



   Relay 110 'is energized on the following circuit, at the end of the time allowed by its sticking delay: battery, electro S' and its rotation contact s ', resistor Re 41, relay 110', R 1452, R 1402, R 1392, R 1382, T 1052, T 1291, earth. Relay 109 is energized by T 1101 '. Electro S 'which could not be excited through relay 1101, is excited by: battery, electro S' and its rotation contact s', T 1094, T 1092, T 1291, earth. Relay 110 'takes off, short-circuited by the excitation earth of electro S', the latter then being maintained through resistor Re 42. The relay 109, having its open circuit at T 1101 ', takes off, opening in T 1092 the circuit of the electro S' which advances the wipers of the associated combiner to position 6, and thus prepares the return of the first non-trailing digit. duit.

  <Desc / Clms Page number 56>

 



   The same device is used when a code of less than eight digits is received (call from an attendant, for example), to switch to automatic rotation one. or several of the positions 6 to 9 of the combiner S ', which correspond to the return of the untranslated digits.



   If, after releasing the translator, the various selections were not made after a determined period of time, for one reason or another, the recorder is released according to the following process. After releasing the translator, relay 116 takes off and prepares in R 1163 for switching on the AC, me Ca 41.



  When the latter closes its contact, the following circuit is completed: berre, cam Ca 41, T 1293 ', R 1163, upper winding of relay 156, battery. Relay 156 sticks and is completed by a holding circuit via T 1561, R 1093, T 1291, earth.



  When the Ca 42 cam closes its contact, the relay 156 'is energized through T 1562. A return signal is then sent to the central departure on the following circuit: generator Gfs, capacitors C43 and C44, T 1561 'and T 1562', transformer TR4, wires 1874 and 1875 When the Ca 42 cam opens its contact, the relay 156 'takes off and the return signal ends. The outgoing exchange becomes free and in one way or another causes the release of all transit exchanges. The recorder in question is disconnected from the corresponding selector; the relays 116 and 129 having their open circuit on the wires 1874, 1375 and 1876 take off and cause all the other components to return to rest.



   It can happen that the reception of the different digits is done at a faster rate than the retransmission, it is necessary to avoid then that a digit can be retransmitted before having been completely recorded. If, for example, the recorder is about to retransmit the 5th digit (1st digit not translated), the combiner S is in position 5, and the electro S 'is glued by T 1092. If the sem number is not completely

  <Desc / Clms Page number 57>

 received relay 128 is at rest and relay 109 is maintained by battery, relay 109, T 1095, T 116, R 1286, contactor e of combiner S 'in position 5, earth. The electro S 'is blocked by T 1092 and the switch of the combiner to position 6, on which the retransmission of the 2nd digit is normally carried out, cannot take place.

   The same reasoning is valid for the 6th, 7th and 8th digits.



   It is obvious that the preceding descriptions have been given only without limitation, and that one could, in particular, relay the routing of the call by recorders translators in two or more. intermediate points, provide higher capacity recorders, imagine other codes than those which have been indicated, increase the number of translated combinations, for the same code received, and this without departing from the scope of the invention.


    

Claims (1)

ABSTRACT. Improvements to long-distance telephone systems making it possible to speed up the establishment of communications, characterized by the following points taken together or in isolation: 1) - the routing, from an outgoing exchange, of communications intended for different zones which must be reached through the same intermediate exchange, is only controlled as far as said intermediate exchange, from which are sent the selection signals necessary to provoke the rest of the routing, these different zones being considered, for the outgoing exchange, with respect to the intermediate exchange, as constituting a single zone. 2) - the numerical combination necessary to determine the routing from the outgoing exchange to the incoming exchange may include a variable number of digits, the smaller the more the end point is generally more distant, if care has been taken, in the context of national numbering, to give said <Desc / Clms Page number 58> numbering structure based on regional considerations. 5) - to speed up the selection and to reduce the size and number of translators, the recorder that receives the requested number is temporarily associated with a simplified primary translator that can receive a small number of digits and which determines the routing of the communication if this number is sufficient to determine it, said translator being taken only after reception by the recorder of the digits which characterize it and being released as soon as it has sent the signals. selection controls controlled by the recorder. The number of primary translators, all identical, is notably lower than that of recorders. 4) - when the number of characteristic digits necessary to determine the routing is greater than the capacity of the primary translator, said primary translator chooses a secondary translator, from the group corresponding to the first characteristic digits, which receives the sequence of characteristic figures and determines the routing. Secondary translators are re-interpreted into different groups which are all accessible to primary translators. 5) - the translator transmits to the recorder, in addition to the selection combinations, an additional combination which fixes the duration of the time interval during which the different selections must be made. 6) - when the association of the recorder and the translator, or the steps of translators between them, is made to. Through a finder, the stop circuit of said finder is used for the transmission of a selection signal. 7) - the stop circuits of the normal tracks and of the diverted ways are put in parallel through suitably oriented rectifiers, so as to prevent false orientations in the event that a diverted channel is taken for routing. <Desc / Clms Page number 59> two communications coming from two different normal channels. i Antwerp,