DE1260544B - Central for evaluating the feedback signal in a telecontrol system for remote control of additional equalizers as well as for monitoring and locating faults in carrier frequency wide-area traffic systems - Google Patents

Description

Central unit for evaluating the feedback signal in a telecontrol system for remote control of additional equalizers as well as for monitoring and fault location in Carrier-frequency wide-area traffic systems The invention relates to a control center for evaluation of the feedback signal in a telecontrol system in carrier frequency wide area systems with many, especially above-ground main offices and remote-fed from them, preferably underground repeaters with individual additional equalizers, belonging to different coaxial lines and placed in different main offices are, timed one after the other for automatic adjustment and the Operating state of the transmission system is monitored.

It is a remote control device for remote control of additional equalizers known for multi-channel carrier frequency wide area systems (German patent 1159 033), via one of the coaxial pairs or via an accessory cable Individual control signals are sent to the remote control office and in each main office are received and there an irreversible, n-stage binary receive counter press with 2n possible positions that are run through in one cycle, which, after receiving the corresponding remote control pulses, the corresponding equalizer caused to set, whereby a comparison counter running in the control center identifies the remote-controlled equalizer.

It was also proposed that remote monitoring and fault location be implemented in Carrier-frequency long-haul systems in such a way that they are carried out by the control center Individual remote monitoring pulses one after the other via a coaxial pair or via an accessory cable sent out and received in every main office and there a person who is known per se, Actuate the irreversible, n-stage binary receive counter that counts after receipt of the corresponding remote monitoring pulses activates setting transistors that send back a binary-coded feedback signal to the control center with the aid of the reception counter initiate where it is determined which office does not have an acknowledgment signal when it is triggered or has sent back a specially marked feedback signal.

The arrangements for remote control and remote monitoring are so similar to each other that they are combined into a single telecontrol system can.

A feedback signal consists of a preparation pulse, an or several alarm pulses to identify errors and from a binary-coded one Pulse telegram with a maximum of h characters, which identify the reporting point. The pulse telegram is coded with the help of the reception counter in the main offices. In the control center there is a running binary comparison counter, each of which has the same position as the reception counter. There is also a feedback signal receiver there needed, which decodes the coded feedback signal and determines which point has reported back. If an alarm pulse occurs or if there is no Feedback signal, an alarm must be given and further remote control or remote monitoring pulses can be prevented. To check whether incorrect impulses are not present have incorrectly advanced any receive counter, the received Feedback signal compared with the position of the comparison counter.

In the arrangements described above, the received in the center Feedback signal decoded by means of a decoding matrix and used to set n independent bivibrators are used. At the end of the feedback signal, the position of the above-mentioned bivibrators with the setting of the comparison counter by means of a Coincidence comparison matrix compared. If the positions of the decoded coincide The feedback signal storing bivibrators and the comparison counter is another Remote control or monitoring pulse sent out. In the event of incoincidence, an alarm bivibrator is activated stimulated and given the alarm. The effort for storing the feedback signal in the bivibrators and for the coincidence comparison in the coincidence comparison matrix is very big.

The aim of the invention is to reduce the effort in the feedback signal receiver to reduce significantly. According to the invention, this is achieved in that the coincidence comparison after every possible one Feedback pulse takes place in such a way that each received feedback impulse stimulates an alarm bivibrator, which by coincidence a subsequent reset pulse passed through the decoding matrix into its Rest position is returned that in the absence of a feedback pulse and coincidence neither the alarm bivibrator is excited nor a reset pulse via the decoding matrix is let through and that in the event of incoincidence either a received feedback pulse no reset pulse follows or, in the absence of a feedback pulse, a reset pulse is allowed to pass through the decoding matrix and stimulates the alarm bivibrator.

The mode of operation of the feedback signal receiver is illustrated using the schematic circuit in FIG. 1 explained. The feedback pulses are filtered out, amplified, rectified and checked for length by means of a pulse filter 1F. A received preparation pulse excites a bivibrator Bi, which in turn releases a clock generator TG via a holding diode Dh4, the clock frequency of which is approximately equal to the repetition frequency of the characters of the feedback signal. The clock generator TG operates an auxiliary counter HZ with more than n + 2 positions, which releases the elements of a decoding matrix DM one after the other. With the help of this matrix, the position of a comparison counter VZ running in the control center is compared with the feedback signal and thus it is determined whether the position that is actually being monitored or set has actually reported back.

A binary counter with ld (n + 2) - rounded up to an integer - is used as an auxiliary counter. For z. B. n = 7 levels of the receive counter and the comparison counter ld 9> 3, ie a four-level binary counter is used as an auxiliary counter. Of its sixteen possible positions, nine working positions are then used to evaluate the feedback signal.

According to FIG. 1, there is one element of the decoding matrix. 2 from a pulse gate with a pulse input Ei and a pulse output Ai, which can be unlocked at the control terminal IiS. The pulse inputs and outputs of the individual pulse gates are connected in parallel (input Ed and output Ad of the decoding matrix). The control terminals ISS of the impulse gates are connected via decoupling diodes to the corresponding outputs of the auxiliary counter HZ and to one output (stage) each of the comparison counter (VZ). A pulse gate can only become permeable if it is enabled by both the auxiliary counter and the comparison counter. In every working position of the auxiliary counter, an impulse gate is released by it and blocked or permeable according to the position of the comparison counter.

The clock generator TG has two outputs, one of which is output A1 incremental pulses for the auxiliary counter and the other output A2 pulses to input Ed of the decoding matrix supplies. In every working position of the auxiliary meter, a pulse becomes the input of the decoding matrix, and the last h pulses are corresponding to the Position of the comparison counter let through or not let through.

A bivibrator B2 is connected to an input Ei from the feedback pulses received and at a second common input E2 from the output pulses of the decoding matrix actuated. If there is coincidence between the feedback signal and the position of the comparison counter there are either no pulses at all at the inputs of the bivibrator B2, or a feedback pulse at input El is followed by an output pulse from the decoding matrix at the input E2 of the bivibrator B2. In the case of coincidence, B2 either does not become at all stimulated or after being stimulated by a rumble pulse from an output pulse the decoding matrix is returned to its rest position. In the event of incoincidence, B2 either stimulated by a feedback pulse or by an output pulse from the decoding matrix not retrieved or in the absence of a feedback pulse from an output pulse the decoding matrix excited.

The preparation impulse can excite the bivibrator B2 unhindered. So there must be a pulse from the clock in the first working position of the auxiliary counter TG allowed through the decoding matrix to the second input of B2 unhindered will. The first pulse gate of the decoding matrix is only controlled by the auxiliary counter.

The second (alarm) impulse is of course not triggered by a Counter-impulse at B2 made ineffective, but stimulates B2 unhindered. So it is allowed in the second working position of the auxiliary counter no impulse gate of the decoding matrix be permeable.

The coincidence between each feedback pulse and the position of the associated level of the comparison counter is measured within each cycle of TG. For this purpose, a switching transistor Ts is provided, which is actuated by the clock generator TG and the bivibrator B2. The transistor Ts receives its base current via a base series resistor RB from the operating voltage source. If the bivibrator B2 is not excited, the base current from Ts is sucked off via a holding diode Dit 1 to the output of B2, and Ts is blocked. If B2 is excited by a feedback pulse, the base current of Ts is sucked off during the following half cycle of TG via a holding diode Dtt 2 to the output A1 of the clock generator. The next time the clock is tilted, it is decided whether there is coincidence or not. In the event of coincidence, B2 is brought back to its rest position (or it was not excited at all), the base current of Ts is sucked off via Djli, and Ts remains blocked. In the event of incoincidence, B2 remains or is excited, while output A1 of the clock generator receives high potential and Djt2 is blocked; the base current of Ts is drawn off neither via Diti nor via D112, and Ts becomes conductive. The conductive transistor Ts holds the clock via a holding diode Di "and causes an alarm relay R to respond.

If no alarm has occurred, the transition from the last Working position of the auxiliary counter to its next position of the bivibrator Bi from Auxiliary counter at input Es reset by a pulse. When tilting Bi The auxiliary counter is in its rest position from its output A3 in its rest position held and triggered a monovibrator M, which sends out another Remote monitoring pulse or remote control pulse.

A shift register can be used as an auxiliary counter instead of a binary counter can be used with the appropriate number of levels. Are the Feedback signal transmitter in the main offices so that the correct number feedback pulses can also be followed by a few superfluous pulses the use of a binary counter as an auxiliary counter is an advantage. Because such a one Auxiliary counter certainly has more positions than necessary, and you can use the empty positions the auxiliary counter to block the feedback signal receiver after the last working position of the auxiliary counter. Is z. B. an auxiliary counter with nine working positions and sixteen possible positions are used, it is convenient to use the last four To use positions of the auxiliary counter as blocking positions and the blocking voltage from the fourth flip-flop of the auxiliary counter.

Claims (11)

Claims: I .. Central for evaluating the feedback signal in a telecontrol system in carrier frequency wide-area traffic systems with many, in particular above-ground main offices and from these remote-fed, preferably underground intermediate amplifiers, with the individual additional equalizers belonging to different coaxial lines and located in different main offices, temporally one after the other for automatic adjustment and the operating status of the transmission system is monitored by sending out individual remote control or remote monitoring pulses from the control center via one of the coaxial pairs or via an accessory line and receiving them in each main office and there an h-level binary reception counter with 2a Activate possible positions, which after receipt of the corresponding remote control or remote monitoring pulses, the setting of the corresponding additional equalizer and the sending back of a binary code with the help of the receive counter ierten feedback signal to the control center, and in that a coincidence comparison between the feedback signal and the position of the comparison counter takes place with the help of a comparison counter running in the control center and a decoding matrix controlled by this, characterized in that the coincidence comparison takes place after each possible feedback pulse, in such a way that each Received feedback pulse stimulates an alarm bivibrator (B.,) which, in the event of coincidence , is returned to its rest position by a subsequent reset pulse passed through the decoding matrix (DM) , so that in the absence of a feedback pulse and coincidence, neither the alarm bivibrator is excited nor a reset pulse is released via the decoding matrix and that in the event of incoincidence either a received feedback pulse is not followed by a reset pulse or, in the absence of a feedback pulse, a reset pulse is allowed to pass through the decoding matrix and excites the alarm bivibrator. 2. Central unit according to claim 1, characterized in that the alarm bivibrator (B2) has an input (El) via which it can only be excited by the feedback pulses received, and a second common input (E2) via which it receives the output pulses the decoding matrix (DM) can either be returned to its rest position when it is excited, or it can be excited when it is in rest position. 3. Central unit according to claim 1, characterized in that; that a received preparatory pulse stimulates a bivibrator (B1) which causes the coincidence comparison and that the last output pulse of the decoding matrix (DM) returns this bivibrator (B1) to its rest position and terminates the feedback. 4. Center according to claim 1, characterized in that the decoding matrix (DM) is controlled on the one hand by an auxiliary counter (HZ) and on the other hand by the comparison counter (VZ). 5. Central according to claim 1 and 4, characterized in that one element of the decoding matrix (DM) consists of a pulse gate with a pulse input (Ei) and a pulse output (Ai) which can be unlocked at a control terminal (K,) and that the control terminals of the individual elements of the decoding matrix are connected via decoupling diodes with the corresponding outputs of the auxiliary counter (HZ) and each with an output (stage) of the comparison counter (VZ) (FIG. 2). 6. Center according to claim 1, 4 and 5, characterized in that the pulse inputs (Ei) and pulse outputs (Ai) of the elements of the decoding matrix (DM) to the common input (Ed) and output (Ad) of the decoding matrix are connected in parallel. 7. Central according to claim 1 and 4, characterized in that a clock (TG) with two outputs (A1 and A2) is provided, one of which (A1) incremental pulses for the auxiliary counter (HZ) and the other (A2) pulses for Input (Ed) of the decoding matrix (DM) supplies, and that the clock is held by the bivibrator (B1) in the rest position and released after receiving a preparation pulse. B. Central unit according to claims 1 and 4, characterized in that in the first working position of the auxiliary counter (HZ) a reset pulse from the clock generator (TG) is passed through a pulse gate of the decoding matrix (DM) controlled by the auxiliary counter to the second input (E2) of the alarm bivibrator (B2) will. 9. Central according to claim 1 and 4, characterized in that in the second working position of the auxiliary counter (HZ) no reset pulse to the second input (E2) of the alarm bivibrator (B2) can arrive. 10. Central unit according to claim 1 and 7, characterized in that an evaluation transistor (Ts) is provided which receives its base current via a base series resistor (RB) from the operating voltage source and which via holding diodes (D j1 1 and Dht 2) from the alarm bivibrator (B2 ) and is controlled by the clock (TG) in such a way that when the alarm bivibrator is not excited, the base current of the evaluation transistor is derived via a holding diode (Dh1) to the output of the alarm bivibrator and that in the half-cycle of the clock, in which its first output (A) is low potential has, the base current of the evaluation transistor is derived via the second holding diode (D1,2) to this output. 11. Central according to claim 1 and 10, characterized in that the evaluation transistor (Ts ) holds the clock (TG) in the conductive state via a holding diode (Dhs) and brings a relay (R) to attract. Documents considered: German Patent No. 1159 033.