DE1218531B - Telecontrol system for central monitoring and fault location in carrier frequency wide area systems - Google Patents

Description

Telecontrol system for central monitoring and fault location in long-range carrier frequency systems The invention relates to a remote control system for central monitoring and fault location in long-distance carrier frequency systems with many, especially above-ground, main offices and from these remotely powered, especially underground repeaters, in which the operating status of the transmission system is monitored by a control center will and an error either in a main office or a section between two Main offices localized and also the type of error is determined.

The object on which the invention is based is illustrated with reference to the F i g. 1 explains in which central remote monitoring for m main offices a carrier frequency system is shown schematically. From a surveillance center ÜZ the main offices Hl to Hm via a first double line L1 one after the other interrogated, and via a second double line L, is automatically from the main offices one after the other a response is sent to the control center.

Central monitoring is particularly necessary when the Main offices are unmanned. The remote powering of the intermediate amplifiers between two Main offices are done with direct current over the inner conductors of two of the carrier frequency transmission serving coaxial cable. In general there are two remote feed loops between two main offices, which are each fed by the neighboring main office.

Carrier frequency wide area systems have line regulators with With the help of a pilot voltage, keep the level constant, especially in the main offices. In the event of a sudden drop in the pilot voltage by 0.35-N below its setpoint, the pilot regulator held in position and pilot alarm given.

A distinction can be made between native and non-system malfunctions.

The following types of system malfunctions can occur: a) Failure of the Power supply of a frame of the carrier frequency system in a main office. this is always noticeable in both transmission directions because the line amplifier Both transmission directions in the frame are fed by the same power supply will.

b) Failure of the remote feed of a remote feed loop between two Main offices as a result of cable interruption, cable short circuit or fault in the remote power supply. This is also always noticeable in both transmission directions of a system, because the remote feed loop includes repeaters for both transmission directions. Such a failure is indicated by a relay in the remote feed unit.

c) Interference with a repeater or other device that to a severe reduction in radio frequency transmission capability or to a complete failure of the system. This only works in the disturbed transmission direction noticeable. This fault is reported in the corresponding amplifier or device slot by pilot alarm by means of a pilot alarm relay in the event of the sudden drop mentioned above of the pilot level is indicated by 0.35 N.

d) Reaching the end position of the line pilot regulator. This is not a Disturbance in the true sense, because the transferability is still guaranteed can be. The end position is indicated by a lamp that is connected to an end position transistor receives its electricity.

A non-system error is e.g. B. the failure of the entire line voltage in a main office, with a buffer battery temporarily taking over the supply.

According to the invention, the telecontrol system is characterized in that from the control center to the carrier-frequency transmission in the outgoing direction Serving pair of lines or one after the other via an enclosed double line Remote monitoring pulses sent out, received in every main office there will be a known, irreversible, n-stage, binary receive counter actuate the setting transistors after receiving the corresponding remote monitoring pulses stimulates the sending back of a binary coded with the help of the success counter Feedback signal via the carrier-frequency transmission in the incoming direction Set up serving pair of lines or a supplementary double line to the control center, where it is determined which office has no feedback signal or a special one when activating has returned the marked feedback signal.

A cable can contain several pairs of lines or cables; with p line pairs or tubes, p / 2 independent systems result. In this case it makes sense to use a common remote monitoring system for the entire cable. In addition, the remote monitoring system can be used jointly for several cables and especially for branches. F i g. 2 shows the schematic representation of the part of such a system that is present in each main office of the cable route for the case of a cable with p tubes. A monitoring signal receiver ftE, upon receipt of a corresponding monitoring signal ÜS, switches on a monitoring circuit ÜS1 to US, which causes a feedback signal transmitter RS to transmit a feedback signal to the control center. In addition, the monitoring signal receiver 1 ° tE prepares the feedback signal transmitter RS for gücluelden via a line L; For example, the monitoring and feedback signals can be transmitted as sampled alternating voltages with a constant monitoring carrier frequency and these signals can be filtered out, amplified, rectified and checked for the correct sampling duration using a pulse filter known per se (German patent specification 1133 754), which only evaluates pulses of the prescribed length receive. This ensures that no incorrect pulses can interfere with the monitoring.

The mode of operation of the irreversible, binary reception counter used in each main office is illustrated by the schematic representation of a four-stage, preferably transistorized counter in FIG. 3 explained. This counter comprises four flip-flops F1, F2, F3, F4 with the inputs Ei, and E12, E21 and, E22, E31 and E32, E41 and E42 as well as the outputs All, Ünd A12, 442, and A22, A31 and A32, A41 and A42. The left outputs (collector connections of the Tralsistors) All, 4421, 4431 of the flip-flops F1, F2 and F3 are bad 'capacitors and diodes with the E21, E22 and E "1, E32 and E'41, E42 of the respectively connected to the next flip-flops, _ If pulses arrive at the inputs Eil, E12 of the first flip-flop F1, the counter changes its position with each pulse conductive and all transistors on the right are blocked (cf. switching symbols in Valvo; "Technische Informations für- die Industrie", Issue 1.4, February 1962, pp. 1 to 4). The following table shows the sixteen possible positions of the four-stage reception counter, whereby the conductive state of a transistor is designated with "0" and the blocked state with "L" and the left and right columns for the left and right transistors of the individual flip-flops are valid Position F1 @. F2 F3 F4 1 0 L 0 L 0 L 0 L. 2 L 0 0 L 0 L 0 L 0 LL 0 0 L 0 L 4 L 0 L 0 0 L 0 L 5 0 L 0 LL 0 0 L. 6 L 0 0 LL 0 0 L. 7 0 LL 0 L 0 0 L 8 L 0 L 0 L 0 0 L. 3 0 L 0 L 0 LL 0 10 L 0 0 L 0 LL 0 11 0 LL 0 0 LL 0 12 L 0 L 0 0 LL 0 13 0 L 0 LL 0 L 0 14 L 0 0 LL 0 L 0 15 0 LL 0 L 0 L 0 16 L 0 L 0 L 0 L 0 A counter with n flip-flops can assume 2n different positions. Each position of the counter can be assigned a position that is only blocked when the counter has taken the corresponding position. The setting transistor Tsh in the kth position is connected with the base via n series resistors to those outputs of the n flip-flops which are conductive in the kth position of the counter. For the case n = 4 and k = 9 , FIG. 4 the coupling of the control transistor Ts. Via four series resistors r1, r2, r3 and r4 to the outputs All, A21, A3 and A42 of the four flip-flops that are conductive in this case.

If only one of the aforementioned series resistors is connected to a blocked one Exit, d. H. at the collector of a blocked transistor, then flows through it into the Base of the associated setting transistor has enough base current and this setting transistor remains conductive. Only if all series resistors are on collectors of conductive transistors are connected, the base of the control transistor receives no current, and the Control transistor is blocked. Thus, in every position of the receive counter is only a control transistor blocked; while all other standing transistors remain conductive.

So there are no disruptive couplings between the individual flip-flops arise via the series resistors to the control transistors and their leads, it is advisable to control all outputs of the flip-flops of the receive counter by means of RC elements to decouple and the voltages for controlling the setting transistors not from the Collectors can be removed directly, but behind the RC elements.

The sequence of the monitored points is given in the outgoing lines (outgoing transmission direction) from the control center to the far end and on the return lines (incoming transmission direction) selected from the far end to the control center. this is necessary because of a pilot alarm caused by system errors is propagated in the direction of transmission to the end of the system and a meaningful one Fault location is only possible from the undisturbed side of the line.

The coupling of the setting transistors to the reception counter can be simplified are taken into account when the systematics of the reception counter positions are taken into account. At Hand of an example with four steep transistors per main office for monitoring two independent transmission systems by means of two double lines each, in the case of the four actuating transistors required for this, two for the outgoing Transmission direction and the other two for the incoming transmission direction are used, this coupling will be explained in more detail.

If you look at the table above of the possible positions of the four-stage receive counter, it can be seen that the last flip-flop F4 twice and the penultimate flip-flop F3 changes its state four times within one cycle. So you can use the last two flip-flops of the receive counter with the four steep transistors hardwire uniformly.

You can also see that the two steep transistors of the outgoing Direction of transmission to the same connections of the first two flip-flops F1 and F2 of the receiving counter must be switched, and that the other two steep transistors of the incoming transmission directions to the same, the first-mentioned connections complementary connections of the first two flip-flops of the receive counter switched Need to become. So you can use the base terminals of the steep transistors of the both outgoing and incoming transmission directions via decoupling resistors summarize and jointly via decoupling diodes with the corresponding connections connect the flip-flops of the receive counter.

This arrangement is easy to implement if the number p of line pairs or setting transistors is a power of 2 with an integer exponent a. If this is not the case, d; H. with 2a-1 <p < 29, at the end of each half of the possible positions of the receive counter, a gap of m (Za - p) / 2 positions can be left and the last lnplln2 - rounded up to a whole number - flip-flops des Firmly wire the receiving counter with the steep transistors (m = number of main offices). With six steep transistors, one eighth of all positions is left as a gap. The forward lines are monitored in the first three "octants" of the cycle and the return lines are monitored in the fifth, sixth and seventh "octants".

In the case of a cable with p line pairs or tubes and m remotely monitored main offices, a monitoring signal receiver with a binary reception counter according to the type of FIG. 3 is provided that activates p different setting statuses one after the other after receiving the corresponding remote monitoring pulses. The reception counter must therefore consist of n = [In (mp)] / ln2 steps, where n is rounded up to the nearest whole number.

In the following, the mode of operation of the in FIG. 2 shown schematically Feedback signal transmitter RS on the basis of the block circuit in FIG. S explained in more detail. So that the coded feedback signal corresponds to the point being monitored for coding the binary n-stage reception counter EZ of the monitoring signal receiver (JE is also used. A known ring counter 9Z with at least h -i- 2 levels used for coding. There is also a monostable multivibrator Ml with a pulse duration that is slightly longer than the duration of the feedback signal§, Another monostable Multivibrätor M2 with a pulse duration equal to one Character duration of the feedback signal is an astable multivibrator TGl as a clock with a frequency equal to the repetition frequency of the calibration of the feedback signal is, and a sine generator G1, which is the carrier frequency for the feedback pulses generated, present.

In the idle state, the ring counter RZ is held in its initial position, in which his first flip-flop, except for the one shown on the left, is stimulated on its own.

When a corresponding remote monitoring pulse is received, the pulse filter of the monitoring signal receiver ÜE sends a pulse to the input El of the monostable multivibrator Ml and stimulates it for the duration of a feedback signal. At the same time, the corresponding control transistor is excited, which causes the ring counter to be released. Only then can feedback be given. The multivibrator Ml releases the clock generator TG via a holding diode Dh 1. The clock generator has two outputs at which pulses occur one after the other at the same time interval. One output Ä l supplies pulses to the parallel-connected inputs of two diode gates T1, T2 and further n = 4 diode gates Tr, while the second output A2 supplies switching pulses for the ring counter RZ, which are offset by the cycle time compared to the pulses at output A1. The first diode gate T1 is controlled by the first stage of the ring counter and in front of the setting transistor and allows the first preparation pulse to pass through to the input E2 of the multivibrator M2 when a steep transistor has responded. The second diode gate T2, which is provided for passed messages, is controlled by the second stage of the ring counter and by a switching transistor Ts 1 via resistors R; in the absence of a fault, the switching transistor Ts 1 is blocked and the second pulse is not allowed through. The. remaining diode gates T ,. only let impulses through to the input E2 of the monovibrator M2 when both the stage of the reception counter EZ controlling these diode gates and the corresponding stage of the ring counter FZ via the resistors R unlock the diad gates at the same time. The ring counter, which is incremented by the incremental pulses, unlocks one diode gate one after the other in the cycle of the advanced switching pulses. The input of the monovibrator M2 can only ever reach a combination of impulses that corresponds to the position of the binary counter.The monovibrator M2 is activated by each impulse for a certain time and outputs the sine generator G1 via a holding diode D4,2 free, which gives an alternating current pulse on the line.

The coupling of the four steep transistors, for example, to the rest of the circuit is shown in FIG. 6 shown. The steep transistors ST 1, ST 2, ST 3, ST 4 control via resistors R1, R2, 9,31 94 and a common capacitor G ', a bivibrator BM, with the inputs E3 and E4 and the outputs Ä3 and A4. In the rest position, all control transistors are conductive; output A3 has a high potential and output A4 has a low potential. The ring counter RZ is held in its initial position in the lluhelage by applying a low potential from output A4 via holding diodes (not shown) in the ring counter to the matching inputs of the flip-flops of the ring counter. If one of the steep transistors is blocked, the bivibrator BM, is excited, the holding diodes in the ring counter are blocked, the ring counter is enabled and can fulfill its function in the feedback signal transmitter. At the end of the feedback signal, the bivibrator BM: is brought to rest position by the monovibrator M1 (FIG. 5) by means of a pulse at the input E4, and the ring counter is held in its initial position.

It will now be described in concrete terms on the basis of the individual possible types of errors how the fault location and fault detection works and which additional ones Switching measures are required for this. First of all, it should be noted that In a system with several systems running in parallel, the monitoring system mostly behaves differently than the other monitored systems.

a) Failure of the power supply of a frame in a main office Der The location of the error is determined by determining up to which main office receive and acknowledge the remote monitoring pulses sent by the control center will. In the monitoring system, in the event of a power failure, there is a Frame in the main office automatically ensures that the associated standing transistor cannot be controlled. The same failure occurs in a co-monitored system displayed as follows: A monitoring relay in the power supply module, not shown of the monitored system closes a contact if the power supply fails, to the base connections of the two associated ones, which are decoupled via resistors Switching transistors - this system has a high potential (positive for npn transistors) lays.

b) Failure of the remote supply of a remote supply loop The remote supply devices have alarm relays which respond in the event of an open circuit or short circuit in the remote supply loop or if the remote supply device fails. After responding, these alarm relays change the feedback signal so that it also contains a second alarm pulse after the first preparation pulse. In Fig. 7 shows the control of the switching transistor Ts 1 required for this in the case of a cable with four tubes. The switching transistor Tsl is made conductive via the parallel-connected working contacts -a1, a2, a3, a4 of the four alarm relays of the remote feed devices when a relay is responded and the diode gate T2 (FIG. 5) is opened for the alarm pulse. When activating the corresponding main office, a feedback signal with an alarm pulse is received and the fault location is thus carried out.

In the monitoring system, between the failure of the remote monitoring center facing remote feed loop and the power supply of the frame in which this Remote feed loop feeding main office cannot be distinguished. Because in these In both cases, the defective section is determined by determining the main office up to which the remote monitoring pulses are received and acknowledged will. This distinction is not necessary because this main office is anyway must be sought for the purpose of interference suppression. If you have these two types of errors in the monitoring However, if you want to differentiate between the system, you can use two remote monitoring centers at both ends of the system and locate the fault from both sides. Here it is necessary that remote monitoring pulses and feedback pulses are different Have length.

c) Disturbance of the high-frequency transmission path The associated pilot alarm relay closes a normally open contact parallel to the steep transistor when responding, so that this becomes ineffective when actuating. The faulty section is determined by that it is determined which steep transistor does not respond when activated.

This malfunction is caused by a failure of the power supply to a rack easily differentiated, because only one direction of transmission is affected.

d) Reaching the end position of the line pilot controller The end position transistors change the feedback signal after their response so that, similar to the failure of a remote feed loop, it contains an alarm pulse after the first preparation pulse. This takes place in the circuit according to FIG. 7 in that the end position transistors apply high (positive) potential to the base of the switching transistor Ts 1 after their response via decoupling diodes D ", D, 23 De 3, Deo and a center-tapped resistor Re + Rl Above-ground location or in each main office, so that the feedback signal with alarm pulse is only sent back when this steep transistor is triggered and an end position is simultaneously present. If the associated steep transistor has not responded and is conductive, it holds the center tap of the resistor via a diode D s4 Re + Rd at low potential and the switching transistor Ts 1 does not receive any base current.

The distinction between whether an end position has been reached or a different one There is an error is very simple, because the feedback signal occurs with an alarm pulse only when activating the steep transistor assigned to the end position indicator.

c) Non-system malfunctions Non-system malfunctions can also can be located via the remote monitoring system. This can be done in any above ground Place a certain control transistor in each main office for each non-system error are assigned so that when driving this control transistor and at the same time If the corresponding error is present, a feedback signal with an alarm pulse is returned.

Like F i g. 7 shows, a relay (not shown) with a normally open contact bi, b2, b3 is assigned to each type of disturbance for, for example, three different types of disturbance outside the system. If one of the three errors occurs, the associated relay applies a high (positive) potential to the base of the via a center-tapped resistor Ra 1-I-Rb i or Ra 2 -f-Rb 2 or R "" + Rb 3 assigned to it Switching transistor Ts 1. The center taps of the resistors are each connected to the collector of the associated control transistor via a diode D. i or D "or D". If this has not responded and is conductive, it keeps the center tap of the associated resistor at low potential via the associated diode, the switching transistor Ts 1 receives no base current through the associated relay contact and remains blocked. Only when the associated control transistor is activated and responds, the associated diode is blocked, the switching transistor Ts 1 conductive and a feedback signal with an alarm pulse is sent back.

A non-system error can result from the failure of a remote feed loop or can be distinguished from the reaching of an end position by the fact that the feedback signal with alarm pulse only when activating a single setting transistor and not when all control transistors occurs in the main office.

If z. B. the operating voltage of the main offices from a network Converter is removed, the batteries buffer, so the failure of the mains voltage or the converter is displayed by a relay actuated by the converter will.

The mode of operation of the feedback signal receiver in the control center and the other control devices is illustrated below with reference to the schematic circuit in FIG. 8 explained. The feedback signal receiver consists of an amplifier V, rectifier Gl and a pulse filter F. To evaluate the feedback signal, there is also a monovibrator M3 with a pulse duration that is slightly longer than the duration of the feedback signal, a clock generator TG with a frequency equal to Repetition frequency of the characters of the feedback signal, a binary auxiliary counter HZ with ln (n + 1) / lh 2 - rounded up to an integer value - levels (with n = 4, i.e. with three levels), a binary comparison counter VZ with n = 4 levels and n + 2 individual bivibrators Bog Bi . . . B "and B,. Provided. The output of the pulse filter F is also provided via n + 1 diode ports T ,,, which are supplied by the auxiliary counter HZ via the series connections of resistors (three resistors per diode port), decoupling diodes and via connections not shown in the figure the associated terminals K1, K2, K3, K4, K5, K, are connected to the inputs of the bivibrators B, ... En. When a preparation pulse is received, the monovibrator M3 responds and outputs Dh, the Clock generator TG 2 free, which emits a pulse after a certain small delay on the auxiliary counter HZ, which is followed by further pulses in the rhythm of the clock frequency brought the position necessary to receive the feedback signal, namely the same position as Bog Bi etc. The incremental pulses from the clock generator TG2 leave the auxiliary counter HZ take its n + 1 utilized positions one after the other in the rhythm of the clock and symbol frequency and successively switch through the n + 1 diode gate Th so that the h + 1 possible feedback pulses in their chronological order the corresponding bivibrators B,. . . B, can activate. If any impulse is missing, the corresponding bivibrator also remains in its rest position. The comparison counter VZ, which is constructed in the same way as the receive counters present in the monitoring signal receivers and is actuated by the monitoring pulses sent out, has the position that the receive counter that has just been reported back should have. If the correct position reports back, the flip-flops of the comparison counter and the corresponding bivibrators have Bi . . . B "the same position. If no malfunction has occurred, the bivibrator B remains in its rest position. The coincidence of the comparison counter and the bivibrators Bi to B is evaluated, for example, in such a way that after receiving the feedback signal from Monovibrator M3, when it returns to its rest position, sends an emitted pulse via 2 n diode gates Te, which are controlled in pairs by the associated coincident bivibrators Bi to Bn and those of the comparison counter and which each work on two identical primary windings of a differential transformer ÜD.

The n differential transformers are the same on both windings Impulse voltages arise, the series connection WS of the secondary windings of the above Differential transformer ÜD remain de-energized, input E5 of bivibrator B, received no excitation pulse and therefore B, do not respond. Another from Monovibrator M3 monovibrator excited when it returns to its rest position M4 with the pulse duration of a monitoring pulse gives the not shown, sine generator available in the control center, which generates an additional monitoring pulse sends out.

If the feedback signal contains an alarm pulse, the bivibrator B is excited, which in turn excites the bivibrator B via a connection (not shown). The bivibrator ET gives an alarm and prevents the transmission of a further monitoring pulse by holding the monovibrator M4 via a holding diode Dh 4.

Occurs as a result of a missing pulse that erroneously affects any receive counter continues, no coincidence between the bivibrators Bi to B and the flip-flops of the comparison counter VZ, the transformer is created in some primary winding ÜD a pulse voltage that is not associated with an equal pulse voltage in the Winding is compensated. The bivibrator Br, which consists of the series connection WS of the Secondary windings of the differential transformer via one between the terminals E, existing connection receives an impulse, responds, gives an alarm and prevents sending out another monitoring pulse.

Possible asymmetry errors of the differential transformer ÜD preferably rendered harmless by using cores for the transformers, whose hysteresis shows a rectangular shape and at which an output voltage is only then builds up when the resulting magnetic flux of the core a certain has exceeded a fixed value (response threshold).

A known remote control device for remote control of additional equalizers used for carrier frequency wide area systems (German patent specification 1159 033) a technique similar to that described above. The telecontrol system according to the Invention can now be expanded so that it can be used for both remote monitoring and fault location as well as for remote control of additional equalizers can be. The additional effort is very low here.

If a particular non-system malfunction is to be detected quickly, so you can either keep the remote monitoring system permanently in operation and all of them Query positions one after the other or assign them to errors that are independent of the system Fault relay cause a special signal to be sent back to the control center.

Sending back a special external error signal to the control center can be implemented as follows: When a non-system error occurs The monovibrator present in every feedback signal transmitter is activated by a contact M2 excited and causes the generator G1 to send a single feedback pulse (Fig. 5). This acts like a preparation impulse in the feedback signal receiver which triggers the monovibrator M3 (FIG. 8) and thus a coincidence comparison. Since the rest of the feedback signal is missing, an alarm is given due to a lack of coincidence.

You can also include a further alarm pulse in the feedback signal and, in connection with the actuating transistors, options for reporting back further create non-system errors.

Likewise, by querying several setting transistors in one Main office and combination of their feedback signals (presence or absence of the alarm pulse) Create criteria for further non-system error types.

The error displays in the control center can be automated.

There are still various possible variations to the remote monitoring system to expand and get more feedback. We shall not go into this further will.

Claims (34)

Claims: 1. Telecontrol system for central monitoring and fault location iri carrier frequency long-distance traffic systems with many, in particular above-ground main offices and remotely fed from these, in particular underground intermediate verses, in which the operational status of the transmission system is monitored by a control center and a fault is either in a main office or a section between two main offices is located and the type of error is also determined; characterized in that individual remote monitoring pulses are sent out one after the other from the control center via the line pair serving for carrier-frequency transmission in the outgoing direction or via an additional double line, are received in each main office (Hi to Hm) and there a well-known, irreversible, n-level binary receive counter (F i g. 3), which, after receiving the corresponding remote monitoring pulses, stimulates control transistors (ST 1, ST 2, ST 3, ST 4) that send back a Rüdkirield signal, which is binary-coded with the aid of the receive counter, via the incoming carrier-frequency transmission Arrange the direction-serving line pair or an additional double line to the control center, where it is determined which office did not return a feedback signal or a specially marked feedback signal when it was triggered. 2. Telecontrol system according to claim 1 for use on a cable with p line pairs or tubes and p / 2 independent systems, characterized in that a common Remote monitoring system for the whole cable is used. 3. Telecontrol system according to Claim 1 and 2, characterized in that the remote monitoring signals and the Feedback signals from one or more sampled AC voltage pulses more suitable Carrier frequency and duty cycle exist. 4. Telecontrol system according to claim 1, characterized in that the setting transistors (Ts9) via n resistors (r1, r2, r3, r4) to the corresponding outputs (A11, A21, A31, A42) of the n flip-flops (F1, F2, F3, F4) of the reception counter are connected (Fig. 4). 5. Telecontrol system according to claim 1 and 4, characterized in that all outputs the flip-flops of the reception counter-means RC elements are decoupled and the Voltages to control the standing transistors do not come from the collectors of the transistors of the reception counter directly, but behind the RC elements. 6th Telecontrol system according to Claim 1, characterized in that the sequence of monitored points on the outgoing lines (outgoing transmission direction) from the Central to the far end and at the return lines (incoming transmission direction) dialed from the far end to the central office. 7. Telecontrol system according to claim 1, 2 and 6, characterized in that the last lnp / lh 2 - rounded up to an integer - flip-flops of the receiving counter with the standing transistors are uniformly hard-wired. B. Telecontrol system according to Claim 1, Z, 4, 6 and 7, characterized characterized in that the base connections of the setting transistors of the p / 2 outgoing lines and the p / 2 return lines via decoupling resistors. iüitdiiiander are connected and together via coupling diodes with the corresponding connections of the remaining ones Flip-flops of the receive counter are connected. 9. Telecontrol system according to claim 1 and 2, characterized gekehrizeichriet that a known ring counter (RZ) with ra -I- 2nd stages is used for coding the feedback signal, that after a received remote monitoring pulse, the pulse filter of the remote monitoring receiver (UE) eingri Iiiipuls to the input (Ei) of a monostable multivibrator (N11) and excites it for the duration of a feedback signal, which releases a clock generator (TG,) via a holding diode (Dh 1) , which in turn from an output (Al) Inäpulse to the parallel-connected Inputs from the receiving counter (EZ) and the ring counter (RZ) controlled n diode gates (P,) supplies and from a second output (A2) shifted by half a time for the ring counter (P2) supplies, and that one pulse each Via one of these diode three to a further moon-stable multivibrator (M2), which in the excited state releases the Siiiu§generatör (G1) for a duty cycle, only then arrives when eriii this diode gate is unlocked by both the ring counter (RZ) and the receiving counter (EZ) (Fig. 5). 10. Telecontrol system according to claim 1, 2 iiüd 9, characterized in that that over eiii Diödentor (T1), that from the first rlip-flop of the ring counter (RZ) and is controlled by the adjusting switches, a first pulse as a preparation pulse of the feedback signal is triggered. 11. Telecontrol system according to claim 1, 2, 9 and 10, characterized in that a Diödentor (T2), which is controlled by the second flip-flop of the ring counter (RZ) and a Schalttrail§istor (Ts t) , a second pulse is triggered as an alarm pulse of the feedback signal. 12. Telecontrol system according to claim 1, 2, 9 and 10, characterized in that all control transistors (e.g. four) in a main office via resistors (R1 to R4) and a common aiheii Capacitor (C1) a bivibrator (BM,) with two inputs (E3 and E4) and two Control outputs (A3 and A4), the output (A4) in the rest position via holding diodes applies low potential to the appropriate inputs of the flip-flops of the ring counter and holds the ring counter in its initial position, so that when locking one The control transistor of the Bivibrätor (BM,) is excited, the holding diodes in the ring counter locked, the ring counter is released and its function in the feedback transmitter can meet (Fig. 6). 13. Telecontrol system according to claim 1, 2 and 12, characterized characterized in that at the end of the feedback signal of the bivibrator (BM,) by the Monovibrator (1V11) brought to its input (E4) by means of a pulse will-. 14. Telecontrol system according to claim 1 and 2, characterized in that a gekeniizeichüet Failure of the power supply of a frame in a main office is located so that It is determined up to which main office the remote monitoring pulses are received and be acknowledged. 15. Telecontrol system according to claim 14, characterized in that that a monitoring relay in the power supply module of the monitored system If the power supply fails, a contact closes which is connected to the via resistors decoupled base connections of the two associated control transistors of this system high potential (positive for npn transistors). 16. Telecontrol system according to Claim 1, 2 and 11, characterized in that a failure of the remote feed with Help `the feedback signals containing an additional alarm pulse located will. 17. Telecontrol system according to claim 16, characterized in that the switching transistor (Ts 1), which controls the diode gate (T2) for the alarm pulse, via the parallel-connected Working contacts (a1, a2, a3 and a4) of the alarm relays of the remote feed devices when responding a relay is made conductive (Fig. 7). 18. Telecontrol system according to claim 1, 16 and 17, characterized in that two remote monitoring centers on both Ends of the system are provided that allow fault location from both sides. 19. Telecontrol system according to claim 1 and 2, wherein pilot alarm relay in the main offices are present, which in the event of a sudden drop in the pilot level by z. B. 0.35 X respond, characterized in that the associated pilot alarm relay when responding a normally open contact closes in parallel to the associated control transistor. 20. Telecontrol system according to claim 1, 2 and 11, wherein in the main offices pilot-operated line regulators are present, characterized in that an end position of a line regulator with With the help of a feedback signal containing an alarm pulse is located. 21. Telecontrol system according to claim 20, characterized in that those present in the line regulator End position transistors when reaching an end position via decoupling diodes (De 1 to D '4) and a middle-tapped resistor (R, + Rd? High potential to the base put the switching transistor (Ts1); where the center tap of the resistor (Rc + Rd) Via a diode (Ds 4) with the collector of one of the end position monitoring assigned Control transistor is connected (P i g. 7). 22. Telecontrol system according to claim 1, 2 and 11, characterized in that system-alien disturbances with the help of a one Feedback signal containing an alarm pulse can be located. 23. Telecontrol system according to claim 22, characterized in that each non-system type of error is assigned a relay with normally open contact (bi, b2, b3), which when responding via a center-tapped resistor (Ra 1 + Rb 1, Ra 2 + Ra 2, Ra 3 + Rb 3) applies high potential to the base of the switching transistor (Ts1), the center tap of this resistor being connected via a diode (. ». S 15 DS 2, D5 3) to the collector of a standing transistor assigned to this type of error (F i g. 7). 24. Telecontrol system according to claim 1, 9 and 10, characterized in that the preparation pulse of the feedback signal in the remote monitoring center excites a monovibrator (M3) for the duration of a feedback signal that releases a clock (TG) via a holding diode (Dh3) in turn actuates a binary auxiliary counter (HZ) with h + 1 possible positions so that the auxiliary counter (HZ) sends the output of the feedback signal receiver to n + 1 independent bivibrators (B. , Bi to Bn) and that the individual pulses of the feedback signal adjust these bivibrators according to their coding (FIG. 8). 25. Telecontrol system according to claim 24, characterized in that the coincidence between n of the n + 1 independent bivibrators (Bi to Bn) and the comparison counter (VZ) running in the center is measured in such a way that one after receiving the feedback signal from the monovibrator (M3) when it returns to its rest position, the pulse emitted via 2 h diode gates (Te), which are controlled in pairs by the associated coincident bivibrators (Bi to B,) and those of the comparison counter (VZ), to two identical primary windings of a differential transformer ( ÜD) is given and that the series connection (Ws) of the secondary windings of the n differential transformers (ÜD) is connected to the input (E3) of a further bivibrator (B,.) (Fig. 8). 26. Telecontrol system according to claim 25, characterized in that that in. Coincidence of the differential transformer via the secondary windings (ÜD) controlled bivibrator (B,) is not excited and that another monovibrator (M4), which is excited simultaneously with the coincidence measurement, a sine wave generator (G2) releases for a key duration, which sends out another remote monitoring pulse (Fig. 8). 27. Telecontrol system according to claim 24, characterized in that im In the event of the mismatch, the bivibrator (B,.) Is excited, triggers an alarm and in turn The monovibrator controlling the sine wave generator (G2) is controlled via a retaining diode (D / 14) (M4) so that no further remote monitoring pulse is transmitted (F i G. 8th). 28. Telecontrol system according to claim 24, characterized in that a back-reported Alarm pulse via the first of the diode gates (T ,,) stimulates the bivibrator (B), which in turn via the bivibrator (B @ triggers alarm and sending out another Remote monitoring pulse prevents (Fig. 8). 29. Telecontrol system according to claim 1, with additional equalizers available in the main offices by means of a remote control are set, characterized in that the Feruffektanlage expanded that it is used for remote monitoring and fault location as well as for remote control the additional equalizer can be used. 30. Telecontrol system according to claim 1, wherein in particular, non-system malfunctions are to be detected quickly, characterized in that that the telecontrol system is kept in operation and all positions one after the other be queried. 31. Telecontrol system according to claim 1, wherein in particular non-system Disturbances are to be recognized quickly, characterized in that the corresponding Fault relays assigned to non-system errors in the corresponding main office at Response causes a special signal to be sent back to the control center. 32. Telecontrol system according to Claim 31, characterized in that when one occurs non-system error through a contact of the associated external error relay of the The monovibrator (M2) present in each feedback signal transmitter is excited and the generator (G1) is caused to send a single feedback pulse. 33. Telecontrol system according to claim 1 and 11, characterized in that a further alarm pulse in the Feedback signal is provided, which can be used in conjunction with the setting transistors to report further non-system errors. 34. Telecontrol system according to claim 1 and 11, characterized in that by interrogating several control transistors in a main office and combination of their feedback signals (presence or absence of the alarm pulse) criteria for further non-system error types are created. Considered publications: German Patent Specifications No. 1133 754, 1159 033; V a 1 v o, "Technical Information for Industry", no. 14, 1962.