SU906018A1 - Device for interfacing telegraph sender with communication line - Google Patents

Description

The invention relates to switching equipment and data transmission equipment and can be used in telegraph devices for generating and transmitting signals to a communication line.

A device for interfacing ⁵ telegraph transmitters with a communication line, containing four output line current switch with galvanic isolation of the input and output circuits included in a pi bridge circuit, and a linear voltage source tl].

However, the known device does not provide pairing with a single-pole or bipolar communication line.

The purpose of the invention is to provide a connection with both a unipolar and a bipolar communication line.

The goal is achieved by the fact that in the device for interfacing the telegraph transmitter with the communication line, containing four output line current switches with galvanic isolation of input and output circuits connected by a bridge circuit, and a line voltage source, seven NAND elements are introduced, an OR element, three inverter, trigger, two differentiating elements, delay element, optoelectronic switch, initial installation unit, valve, stabilizing element, optoelectronic switch and output rectifier connected directly clearly and through a stabilizing element with an optoelectronic switch, the output of which is connected to the first input of the first AND-NOT element and the input of the first inverter, the output of which is connected to the first input of the second AND-NOT element, while the second inputs of the first and second AND-NOT elements are connected with the output of the delay element, the input of which is connected to the output of the OR element, the first input of the third INE element is connected to the output of the initial installation unit and to the second inputs of the fourth and fifth AND-NOT elements, the second input of the third AND-NOT element from the outputs of the second inverter, the input of which is connected to the first inputs of the fourth and sixth AND-NOT elements, the output of the fourth AND-NOT element is directly connected to the inputs of the first and second output line current switches, and to the first input of the OR element through the first differentiating element, the inputs the third and fourth output line current switches are connected to the output of the fifth AND-NOT element, the first input of which is connected to the output of the seventh AND-NOT element, the first input of which is connected to the output of the sixth AND-NOT element the input is with the output of the third AND-NOT element directly, and with the second input of the OR element through the second differentiating element, the second input of the sixth AND-NOT element is connected to the first output of the trigger, the second input of which is connected to the input of the third inverter and to the third input of the third element AND NOT, the trigger inputs are connected to the outputs of the first and second elements AND NOT, the first and fourth output line current switches are connected to the valve and the positive pole of the line voltage source, are the second and third output switches The line current is connected directly to the valve, and to the negative pole of the line voltage source through an optoelectronic switch, the second input of which is connected to the output of the third inverter.

The drawing shows a structural electrical diagram of the proposed device.

A device for interfacing a telegraph transmitter with a swazi line contains the first, second, third and fourth output line current switches 1-4, respectively, an optoelectronic switch 5, valve 6, a line voltage source 7, an output rectifier 8, a stabilizing element 9, an initial installation unit 10, optoelectronic switch 11, OR element 12, first, second, third, fourth, fifth, sixth and seventh AND-NOT elements 13 19, respectively, first, second and third inverters 20 - 22, respectively, trigger 23, delay element 24, the first and • Ora differentiating elements 25 and 26, respectively, input bus 27 and two output buses 28 and 29, moreover, shows linear load 30 and external battery 31.

The device operates as follows.

If the linear path is prepared for • on-off operation, i.e.

_{5, a} linear load 30 corresponding to the bipolar mode is connected to the output buses 28 and 29, then there is no external battery 31, which in the single-pole mode can be connected either from the U side of the transmitter or from the receiver side. When the power source (not shown) are simultaneously switched on voltage source line 7 and the unit 10 the mouth ₁₅ Novki starting pulse generates an initial installation, the duration corresponding to, e.g., the duration of the elementary telegraph parcels and the level corresponding to the level of logic O '. The logic level '0' goes to the fourth and fifth inputs of the third AND-NOT 15 element, as a result of which the logical level * 1 appears at their output. The presence of a logical '1' at their outputs ensures the closed state of all output switches of line current 1 to 4, as a result of which there is no current in the line load 30, and consequently there is no voltage on the input diagonal of the output rectifier 8. Therefore, the current does not flow through the optoelectronic switch 11 and at its output there is a logical level l, which goes to the first input of the first AND-NOT 13 element and the input of the first inverter 20. The first input of the second AND-NOT 14 element from the output of the first inverter 20 logically 'O'. Logical signals * 1, which appeared upon switching on the corresponding AND-NOT elements, are differentiated, as a result of which pulses of short duration are received at the inputs of the OR element. If at least one of the inputs of OR element 12 has a logical pulse * 1 * (or both inputs simultaneously), a logical '1' pulse is generated at its output, which is fed to the input of the delay element 24. A delayed logical '1' pulse of short duration arrives to the second inputs of the first and second elements AND-NOT and 14 (in order to ensure high noise immunity, the delay time is chosen to be approximately equal to half the length ^{ss of the} pulse duration of the initial installation by unit 10). At the moment of arrival of a logical pulse of '1' of short duration to the second inputs of the first and second AND-NOT elements 13 and 14, the logical 1 * signals appear at both inputs of the first AND-NOT element, as a result of which a logical pulse is generated at its output 0 'of short duration, which sets the trigger 23 to a state in which on its second output is logic 1, and on the first output is the level of logical' O '. Logical level '1' from the second p output of trigger 23 goes to the third input of the third AND-NOT element 15 and <choc of the third inverter 22, as a result of which a logical * 0 'appears on its output, which translates on-1 electronic switch 5 into the on state. The logical level 'O' from the first output of the trigger 23 goes to the second input of the sixth element AND-NOT 18 and blocks it, as a result of which its logical level 1 'is constantly set at its 2 output.

After the operation of block 10, the second inputs of the corresponding AND-NOT elements and the first input of the third 2 of the element 15 receives the logical level '1', the state of the trigger 23 does not change and corresponds to the bipolar mode of operation of the device.

The process of transmitting information in two-3-pole mode is as follows.

On admission to the telegraph transmitter on input bus 27 signa- ₃ la logical G '(forming starting parcel) at the output of the fourth NAND logic 1 is generated, causing the output line current switches 1 and 2 naho- dyatsya ₄ in a closed state. The level of logical O 'entering the first input of the sixth element AND NOT does not change its state, since the level of logical ₄ O' is constantly located at its second input. The level of logic '0' from the input bus 27 goes to the input of the second inverter 21, so at its output the level is logical '1', which goes to the second input of the third AND-NOT element, since at that time there is a logical '1 ', at its output a level of logical' O 'is generated, which is fed to the second input of the seventh AND-NOT element 19, at the first input of which logic 1 is constantly present. At the output of the seventh element AND-NOT, a logical' 1 'is generated and goes to the first input of the fifth element AND NOT at the second input which also has a logical '1'. As a result of this, the logical '0' is generated at the output of the fifth AND-NOT element, which switches the line current switches 3 and 4 to the on state. Since in the bipolar mode the optoelectronic switch 5 is constantly open, a negative direction current flows in the linear load 30 (starting package). The threshold for turning on the stabilizing element 9 is selected so as to prevent current flowing through the optoelectronic switch 11 at a voltage on the output buses 28 and 29 not exceeding the absolute value of the voltage of the packages in bipolar mode. Therefore, in the bipolar mode of operation of the device, the optoelectronic switch 11 is in the closed state and at its output there is a logical level of '1 *. At the moment of starting the formation of the starting premise, the logic level '1' from the output of the fourth AND-NOT element through the differentiating element 25 goes to the first input of the “► OR OR 12, and from its output through the delay element 24 to the second inputs of the AND-NOT 13 and 14. After the exposure time, the state of the optoelectronic switch 11 is polled, and therefore the communication line. Since at this time the logical '1 ends at both inputs of the first AND-NOT 13 element at the same time, a logical O' pulse appears at its output, which confirms the previous state of the trigger 23 corresponding to the bipolar operation mode.

Upon receipt of a logical '1' from the telegraph transmitter to the input bus 27 (formation of a stop package), a logical '0' at the output of the second inverter 21 is also generated at the output of the second inverter 21, which is also logic O ', which is fed to the second input of the third element' AND -NOT 15, therefore, a logical '1' is generated at its output. At both inputs of the seventh AND-NOT 19 element, the logical levels are '1', as a result of which a logical '0' is generated at its output, and a logical '1' at the output of the fifth AND-NOT 17 element, which turns off the output current 3 and 4. The presence of a logical '0' at the output of the fourth AND-NOT element ensures that the output switches of line current 1 and 3 are turned on and a positive direction current appears in the linear load 30 (stop signal). When forming the stop premise, as well as when forming the start 5, the state of the optoelectronic switch 11 does not change and the logical level * 1 at its output.

At the time of the start of the formation of the stop package, the logical signal ^G 1 ^G U from the adhoc of the third AND-NOT 15 element through the differentiating element 26, according to the indicated principle, the state of the optoelectronic switch 1 1 is polled and the state of trigger-15 of the gene 23 is confirmed, corresponding to the bipolar mode.

If the line path is prepared for operation in single-pole mode before switching on, then the linear load 30 corresponding to the single-pole mode is connected to the output buses 28 and 29 20 and an external battery 31 is connected in series with it (for example, from the transmitter side). When the power source is turned on (not shown in the drawing) according to the described principle, block 10 generates an initial setting pulse, and for the duration of this pulse, all output line current switches 1–4 are in the off state. As a result, the input da diagonal output rectifier 8 develops a voltage substantially equal to the voltage of the connected external battery 31. The switching threshold stabilizing capstan _35; about element 9 is selected so as to ensure the flow of current through the optoelectronic switch 11 at a given voltage of the external battery. When the output switches of the linear current _{40 are} turned off, regardless of the polarity of the external battery, the output rectifier 8 provides the flow of current through the optoelectronic switch. The value of this current should not exceed the set leakage current of the device in a single-pole mode. The switching threshold of the optoelectronic switch 11 is set so that it is in the on state under the influence of this current, so at that time there is a logical O 'at its output, which is fed to the first input of the first AND-NOT 13 element and the input of the first inverter 20, at the first input the second element AND 14 NOT logical * 1 *. The logical signal * 1 ”, for> 5, which appeared when the voltage source was turned on at the outputs of the corresponding AND-NOT elements after differentiation and delay, is fed to the second inputs of the first and second AND-NOT elements. In this case, the logic 1 signals simultaneously appear on both inputs of the second AND-NOT element, as a result of which a logical O pulse of short duration is generated at its output, which sets the trigger 23 to state, at. which on its second output is logical O, and on its first output is logical Ί.

The level of logical O * from the second output of trigger 23 blocks the third AND-NOT 15 element and permanently logical 1 is set at its output. At the output of inverter 22, it is constantly logical 1, which sets key 5 to the off state. The level of the logical unit from the first output of the trigger 23 goes to the second input of the sixth element AND-NOT 18 and removes the lock from it. After the operation of block 10, the state of trigger 2 3 does not change and corresponds to the unipolar mode of operation of the device.

The process of transmitting information in a single-pole mode is as follows.

Upon receipt of a logical 1 from the transmitter to the input bus 27 (formation of a stop package), a logical O appears at the output of the sixth AND-NOT 18 element, since logic is 1 at its second input, and as a result, a logical l * ', arriving at the first input of the fifth element AND-NOT 17. Since at this moment in time at both inputs of each corresponding INE element there is a logical Ί *, therefore, logical O is generated at their outputs, which translates all output commutations at the same time Linear current regulators 1 to 4 are switched on, and a direct current flows (stop signal) in the linear load 30 from the external battery 31. Depending on the polarity of connecting the external battery 31, the linear current flows either through the output switches of the linear current 1 and 2 and the valve 6, or through the output switches of the linear current 3 and 4 and the valve 6 (the device is not sensitive to the polarity of the external battery). Upon receipt from the telegraph transmitter to the input bus 27 logical O (formation of the starting premise) to you

906018 10 moves of the fourth and fifth INE elements 16 and 17 display a logical '1', as a result of which all output switches of line current 1-4 turn off and a current appears in the circuit 5, which turns on the optoelectronic switch 11 and sets it to its output logical GO '. The logical level 'O' from its output goes to the first input of the first AND-NOT 13 element and the input of the first inverter 20, the logical '1' goes to the first input of the second AND-NOT 14 element. The logical signal * 1 ', which appeared at the output of the fourth AND-NOT element when 15 entered the input bus 27 of a logical' 0 ', after the first differentiation by the AND-NOT 15 element and the delay is supplied to the second inputs of the first and second AND-NOT elements. The logical level of “1” is simultaneously on both inputs of the second AND-NOT 14 element, as a result of which a logical “0” pulse of short duration is generated at its output, which confirms the state of trigger 23 corresponding to the unipolar operation mode.

In a single-pole operation mode, each time a non-current package is formed, the OPTO- »0 state of the elec- tron switch 11 (and, therefore, the line) is interrogated by differentiated pulses and a delay element 24. If the device is switched off in an unipolar • mode, disconnect the external battery and connect the linear battery ₃₅ the load corresponding to the bipolar mode of operation, during the formation of a currentless package according to the described principle, the state of the optoelectronic switch 11 is polled, as a result of which the trigger 23 switches Odita the state corresponding to a two-pole mode of operation, and the device begins to generate current pulses tsvuhpolyarnye. ₄₅

If during operation of the device in zwipolar mode, an external battery, for example, from the receiver’s side, and a linear load corresponding to a single-pole mode are connected, after interrogating the state of the optoelectronic switch 11 by delayed differentiated pulses, the trigger 23 according to the described principle goes into the state corresponding to a single-pole ⁵⁵ operating mode and the device starts forming, the formation of unipolar current pulses. In the bipolar mode of operation of the device, the interrogation of the state of the optoelectronic switch by differentiated pulses occurs both during the stop sending and during the start. This is necessary in order to automatically switch the operating mode of the device to any polarity of connecting the external battery when the external battery is connected from the receiver side. Since the optoelectronic switch 11 is insensitive. to the voltage of source 7, its state in this case should only change when the voltage difference of the external battery and source 7 appears. Since it is difficult to predict on which package (start or stop) the voltage difference appears, the state of the optoelectronic switch is polled on each package.

I

Thus, the proposed device for interfacing a telegraph transmitter with a communication line provides the formation of both tsvupolar telegraph signals and unipolar. This ensures automatic, setting the operating mode of the device depending on the state of the linear path. The device operates not only when the transmitter is turned on, but also during its operation, which is especially important when it becomes necessary to change the operating mode of the transmitter from the side. a receiver remote to a considerable distance from the transmitter (or if the transmitter is operating in automatic mode and is not available to change the operating mode manually).

Claims (1)

The invention relates to switching technology and transfer equipment and can be used in telegraph; devices for forming and transferring signals to a communication line.  A device for coupling a telegraph transmitter with a communication line, which includes four output linear current switches with galvanic isolation of incoming and outgoing circuits connected by a bridge circuit, and a linear voltage source Il3, is known, the known device does not provide brewing coupling as with the pole pole and the pole pole link.  The purpose of the invention is to provide coexistence with both unipolar and bipolar communication lines.  The goal is achieved by the fact that seven I-NOT elements are introduced into the device for interfacing a telegraph transmitter with a communication line containing four output linear current switches with galvanic isolation of input and output circuits connected in a bridge circuit and a linear voltage source. , an OR element, three inverters, a trigger, a color-differentiating element, a delay element, an optoelectronic switch, an initial installation unit, a valve, a stabilizing switch. The AI element, an optoelectronic switch and an output rectifier connected directly and through a stabilizing element to an optoelectronic switch, the output of which is connected to the first input of the first NAND element and the input of the first inverter whose output is connected to the first input of the second NAND element, the second inputs of the first and second elements AND-NOT connected to the output of the element ederzhki, the input of which is connected to the output of the element OR, the first input of the third element AND-NOT connected to the output b. -yuk initial setup and with the second inputs of the fourth and fifth elements AND-NOT, the second input of the third element AND-NN is connected to the output of the second inverter, the input of which is connected to the first entrances of the fourth and sixth elements AND-NOT, the output of the fourth element AND-NOT connected to the gateways of the first and second output switches of the linear current immediately, and to the first input of the element OR through the first differentiating element, the inputs of the third and fourth output switches of the linear current are connected to the output of the fifth AND-NOT element, first in One of which coeds is Ren with the output of the seventh element AND-NOT, the first input of which is connected to the output of the sixth element AND-NOT, and the second input - with the output of the third element AND-NOT directly and with the second input of the element OR - the second differentiating power, The second input of the sixth element AND-NOT is connected to the first output of the trigger, the second input of which is connected to the input of the third inverter and to the third input of the third AND-NOT element, the trigger inputs are connected to the outputs of the first and second Elements NAND, the first to fourth output Switches linear soeoineny of current with positive po7POSOM valve and a source line voltage, the second and third line current output switches connected to the valve directly, and to the negative pole of the linear voltage zhen§1 - through ontoelektronny key, a second input coupled to an output of the third inverter.  The drawing shows a structural electrical circuit of the proposed device.  The device for interfacing the telegraph transmitter with the swap line contains the first, second, third and fourth output switches of the linear T (Zha 1-4, respectively, optoelectronic switch 5, valve 6, line voltage source 7, output rectifier 8, stabilizing element 9, unit 10 of the initial installation, optoelectronic switch 11, element OR 12, first, second, third, fourth, fifth, sixth and seventh elements of the I-LE 13 19 respectively,. the first, second and third inverters 20–22, respectively, trigger 23, delay element 24, first and second differentiating elements 25 and 26, respectively, input bus 27, two output buses 28 and 29, in addition, linear load 30 and external battery are shown 31.  The device works as follows.  If the linear path is prepared for operation in two-position mode, t. e.  A linear load 30, corresponding to the bipolar mode, is connected to the output probes 28 and 29, then the external battery 31, which in the single-pole mode can be connected either from the transmitter or from the receiver, is absent.  When the power source is turned on (not shown in the drawing), the linear voltage source 7 is simultaneously turned on, and the initial installation unit 10 generates a pulse of the initial installation, the duration corresponding to, for example, the duration of the elementary telegraph parcel and the level corresponding to the logic level O.  The logic level O enters the fourth and fifth inputs of the third element AND – YE 15, with the result that the logical level 1 is output at their output.  The presence at their outputs of a logic state ensures the closed state of all output switches of the linear current 1-4, as a result of which there is no current in the linear load of the DA, and there is no voltage on the input diagonal of the output rectifier B.  Therefore, the current does not flow through the optoelectronic switch 11 and at its output there is a logic level 1, which is fed to the first input of the first AND-NE element 13 and the input of the first inverter 2O.  The first input of the second element I-4E 14 from the output of the first inverter 20 receives a logical O.  The signals that are logical, when turned on at the corresponding IS-NOT elements, are differentiated, which results in short-duration pulses at the inputs of the element OR 12.  If at least one of the inputs (the element OR 12 pulse of a logical HCl or on both inputs simultaneously) appears at its output, a pulse of logical 1 is generated, which is assigned to the input of delay 24.  The delayed pulse of logical 1 short duration is fed to the second inputs of the first and second elements AND-NOT 13 and 14 (in order to ensure high noise immunity, the delay time is approximately equal to half the initial pulse duration by the unit 10).  At the moment when a pulse of logical short duration arrives at the second inputs of the first and the first elements of the IS-NO 13 and 14, the signals of the logical 1 appear on both of the first inputs of the AND-NO, resulting in a short pulse of logical O, which sets the trigger 23 to the state in which at its second output is logic I, and at the first output is the logic level O, the logic level from the second output of trigger 23 is fed to the third input of the third element I-LE 15 and jxoa of the third inverter 22, with the result that a logical O appears at its output, which translates the photoelectric switch 5 into the included state.  Urszhen logical O from the first output of the trigger 23 is fed to the second input of the sixth element AND-NOT 18 and blocks it, with the result that the logical level 1 is permanently set at its output.  After the operation of block 10 is completed, the second inputs of the corresponding AND-NES elements and the first input of the third element 15 receive a logic level 1, the state of the trigger 23 does not change and corresponds to a bipolar mode of operation of the device.  The process of transmitting information in bipolar mode is as follows.  Upon receipt from the telegraph (} of the transmitter on the input bus 27 of the logical O signal (formation of the starting loop), a logical I is generated at the output of the fourth AND-NOT element, as a result of which the linear current output switches 1 and 2 are in the closed state .  The level of logical О entering the first input of the sixth Element IS-NOT does not change its state, since at its second input there is a constant logical O.  The logic level O from the input bus 27 is fed to the input of the second inverter 21, so at its output is the logical I level, which goes to the second input of the third NANDEM, since at that time logical is present at all its inputs, its output is generated the level of logical O, which arrives at the second input of the seventh element AND-NOT 19, at the first input of which the logical I is constantly present.  At the output of the seventh element, AND-NO, logical I is generated and fed to the first 86 input of the fifth IS-N element, the second input of which also contains logical I.  As a result, the output of the fifth IS element produces a logical O, which switches the line current switches 3 and 4 to the on state.  Since the optoelectronic switch 5 is constantly open in the bipolar mode, a negative direction current (starting parcel) flows in the linear load 30.  The turn-on threshold of the stabilizing element 9 is chosen so as to prevent current from flowing through the optoelectronic switch 11 when the voltage on the output buses 28 and 29 does not exceed the absolute value of the voltage of the parks in polarized mode.  Therefore, in a bipolar mode of operation of the device, the optoelectronic switch 11 is in the closed state and at its output there is a logic level.  At the moment of starting the formation of the starting parcel, the Urszhen logical I from the output of the quarter-element AND-NOT through the differentiating element 25 enters the first input of the OR element 12, and from its output through the delay element 24 to the second inputs of the I-ЯЕ 13 and 14 elements.  After the exposure time, the state of the optoelectronic switch 11 and, therefore, the communication line are polled.  Since at this time the first IS-NE 13 ends with a logical one at both inputs, a logical O pulse appears at its output, which confirms the previous state of the trigger 23 corresponding to the bipolar mode of operation.  When entering from the telegraph transmitter to the input bus 27 logical I (forming a stop parcel), the output of the corresponding element AND-NOT produces a logical O at the output of the second inverter 21 and also logical O, which is fed to the second input of the third element AND-NOT 15, therefore The output is logically generated.  At both inputs of the seventh IS-NE 19, logic levels appear, with the result that logical O is generated at its output, and logical I at the output of the fifth IS-17 element 17, which leads to switching off the output switches of the linear current 3 and 4.  The presence of logical O at the output of the fourth element AND-NOT ensures that the output switches of the linear current I and 3 are turned on and, in line with the linear load, 30 of the current of the positive direction (stop sending).  During the formation of the stop parcel, as well as during the formation of the starting one, the state of the photoelectric switch 11 does not change and at its output the logical level I.  At the beginning of the formation of the stop package, by a logical I signal with Bj ixoaa of the third element AND –NE 15 through the differentiating element 26, the optoelectronic switch 11 is checked by the differentiating element 26, and the Hera 23 condition is acknowledged corresponding to the bipolar mode.  If the linear path before switching on is prepared for operation in a single-pole mode, then the linear load of the DA and the external battery 31 (for example, on the transmitter side) are connected to the output buses 28 and 29 corresponding to the single-pole mode.  When the power supply is turned on (not yet shown in the drawing) according to the described principle, the unit Yu forms the initial boost pulse, and for the duration of this pulse all the output linear current switches 1-4 are in the off state.  As a result of this, ite of the input diagonal of the encoder rectifier 8 develops a voltage almost equal to the voltage of the connected external battery 31.  Turn-on threshold stabilizing; The cell 9 is chosen so as to allow current to flow through the optoelectronic switch 11 for a given voltage of an external battery.  When the output switches of the linear current are turned off, regardless of the polarity of the external battery connection, the output rectifier 8 allows current to flow through the ptoelectron switch.  The magnitude of this current must not exceed the specified leakage current of the device in single-pole mode.  The turn-on threshold of the optoelectronic switch 11 is set so that it is in the on state under the action of this current, therefore, this time at its output is logical O, which is fed to the first input of the first element AND 13 of the first inverter 20, at the first input the second element AND-NOT 14 is logical 1.  The logical signal, which appeared when the voltage source was turned on at the outputs of the corresponding NAND elements after differentiation and 9 18 delays, arrives at the second inputs of the first and second NAND elements.  In this case, the signals of the logical I simultaneously appear on both inputs of the second NAND element, with the result that at its output a logical pulse of short duration is generated, which sets the trigger 23 to the, at state.  which at its second output is logical O, and at its first output is logical.  The logic level O from the second output of the trigger 23 blocks the third element IS-NOT 15 and at its output a permanent logical 1 is set.  At the output of the inverter 22, a constant logic, which switches the key 5 to the off state.  The level of the logical unit from the first run of the trigger 23 is fed to the second input of the sixth element AND-NOT 18 and removes the lock from it.  After the operation of the block 10 is completed, the state of the trigger 23 does not change and corresponds to the single-pole mode of the device.  The process of transmitting information in a single-pole mode is as follows.  When a logical 1 arrives from the transmitter to the input bus 27 (forming a stop parcel), logical O appears at the output of the sixth element AND-NOT 18, since at its second input there is a constant logical result, resulting in the output of the seventh element, AND-19 Logic I arrives at the first input of the fifth element AND-NOT 17, since at this time, a logical O is generated at both inputs of each corresponding element of the INE, and therefore all the output commutators are generated at their outputs The linear current tori 1 to 4 are in the on state, and a constant current (stop package) flows in the linear load 30 from the external battery 31.  Depending on the polarity of connecting the external battery 31, the linear current flows either through the output switches of the linear current 1 and 2 and the gate 6, or through the output switches of the linear current 3 and 4 and the gate 6 (the device is dependent on the polarity of the external battery).  When posting from a telegraph transmitter to the input bus 27, a logical O (forming a starting parcel) on the top of the fourth and fifth elements, AND- NOT 16 and 17, appears logical I, with the result that all of the outgoing linear current switches 1-4 switch to off the state and in the circuit there is a current leading to the switching on of optoelectronic switch II and the establishment of a logical fO at its output.  The logic level O from its output goes to the first input of the first element NAND 13 and the input of the first inverter 2O, the first input of the second element I-NB 14 receives the logical I Signal of logical 1, which appeared at the output of the fourth element NAND when entering ia the input bus 27 of the logical O, after the first differentiation by the AND-NE element 15 and the delay arrives at the second inputs of the first and second AND-NOT elements.  The logic level 1 simultaneously appears on both inputs of the second element AND-HEN 14, as a result of which a pulse of logical short duration is generated at its output, which confirms its trigger state 23, corresponding to the single-pole mode of operation.  In the single-pole mode of operation, each time a current is formed, the state of the optolektron switch 11 (and therefore the lines) is differentiated by differential pulses and Delay element 24, If the external battery is disconnected and the linear load is connected during device operation in the single-pole mode, corresponding to the bipolar mode of operation, during the formation of the currentless sending according to the described principle, the optoelectronic switch 11 is detected, as a result of which the trigger 23 passes state corresponding to a two-pole mode of operation, and the device begins to form dvuhpol molecular weight (IMpulsy current.  If during device operation in a two-pole mode, an external battery is connected, for example, from the receiver side, and the linear load corresponding to the single-pole mode, after interrogation of the state of the optoelectronic switch 11 by delayed differentiated pulses, the trigger 23 by the described principle switches to the state corresponding to the single-pole operation mode and the device begins to form single-pole current pulses. In a bipolar mode of operation of the device 90 810, a survey of the state of an optoelectronic switch differential pulses occur both during the stop package and during the starting one.  This is necessary in order to ensure automatic switching of the operating mode of the device three times the full capacity of the external battery when the external battery is connected from the receiver.  Since the optoelectronic switch 11 is insensitive to the voltage of source 7, its state in this case should change only when the voltage difference between the external battery and the source 7 appears.  Since it is difficult to predict at which package (starting or stopping) the voltage difference appears, the state of the optoelectronic switch is interrogated on each package.  Thus, the proposed device for conjugating a telegraph (} a transmitter with a communication line provides the formation of both two-pole telegraph signals and unipolar signals.  In this case, an automatic setting of the operating mode of the device depending on the state of the 1st linear path is provided.  The device acts not only when jTepeaaT4HKa is turned on, but also during its operation, which is especially important when it is necessary to change the mode of operation of the transmitter from the receiver remote from the transmitter at considerable distances (or if the transmitter works in automatic mode and is unavailable for changing the mode . manual operation), Invention Apparatus for interfacing a telegraph transmitter with a communication line, comprising a loop of output linear current switch with galvanic isolation of input and output circuits connected in a bridge circuit, and a linear voltage source characterized in that provide interconnection with both single-pole and double-pole communication lines, seven AND-NOT elements, an OR element, three inverters, a trigger, two differentiating elements, a delay element, an optoelectronic switch, a to the initial installation, a valve, a stabilizing element, an optoelectronic switch and an output rectifier connected directly and through a stabilizing element with an optoelectronic switch, the output of which is connected to the first input of the first NAND element and the input of the first inverter whose output is connected to the first input of the second element AND-NOT, while the second inputs of the first and second elements AND-NOT connected to the output of the delay element, the output of which is connected to the output of the OR element, the first input of the third element AND-NOT connected to The output of the initial installation unit and with the second inputs of the fourth and fifth AND-NOT elements, the second input of the third AND-NOT element is connected to the output of the second inverter, whose input is connected to the first inputs of the fourth and sixth AND-NOT elements, the output of the fourth AND element -NOT connected to the outputs of the first and second output switches of the linear current directly, and to the first input of the OR element through the first differentiating element, the inputs of the third and fourth output switches of the linear current are connected to the output of the fifth element AND- E, a first input coupled to an output of the seventh AND-HB, the first input coupled to an output of the sixth AND-NO element, and the second input - with the output of the third AND-NO element directly and with the second input of the OR element - via the second differentiator. element, the second input of the sixth element IS-NOT connected to the first input of the trigger, the second input of which is connected to the input of the third inverter and the third input of the third element IS-NOT, the inputs of the trigger connected to the codes of the first and second elements AND-NOT, the first and fourth output the linear current switches are connected to the valve and the positive pole of the line voltage source, the second and third output linear current switches are connected to the valve directly, and to the negative pole of the linear voltage source - via optoelectronic switch, the second input of which is connected to the output of the third inverter. Sources of information taken into account in the examination I. Kopnochev L.N. Principles of construction of equipment for the transmission of discrete information. M., St. Don, 1972, p. 7O (prototype). St h. 53 85 fcj