DE3407669C2 - - Google Patents

Description

The invention relates to a method for signaling of malfunctions in terminals of text communication directions according to the preamble of claim 1, and instructions for performing this procedure.

To transfer messages between one for text communication intended terminal and a counterpart le, z. B. between a teleprinter and a Ver agency, via a connecting line, are different known transmission method. Basically under one differentiates between the so-called direct current transmission technology and the so-called AC transmission technology. in the the first case you can again between a so-called double electricity and a so-called single current transmission technology separate. In the double flow process, the over Carrying of messages by reversing one on the An end line flowing direct current instead. In which Single stream method, the news is through Ta of the direct current flowing on the connecting line mes transferred. Since the direct current in these cases is one relatively high value, e.g. B. has a value of 40 mA speaks one also from a direct current high level transmission technology. The use of the double stream or the simple current method depends on the circumstances of the existing which network and the requirements, which in detail be put. For example, for a duplex transmission over two independent transmission channels  the double flow method used while for a half-duplex transmission over mostly only one channel the single current method can be used.

The AC transmission technology, in which with one lower level is worked, and therefore often as low-level AC transmission technology is always a duplex system The transmission principle here is that in both directions, i.e. in the direction from the terminal to the Ge remote station and from the remote station to the end device in each case working with a different carrier frequency.

Regardless of the type of transmission technology used nik accepts the call for secure messaging a top priority. Although the devices currently in use, especially with regard to Reliability and functionality meet high requirements are sufficient, malfunctions cannot be excluded. It should be borne in mind that disruptions are not only caused by mistakes ler in the terminal, but also by errors on the over transmission line, d. H. caused on the connecting line can be. In any case, it is always a fast one Respond required. However, this is again ahead setting that the cause of the fault quickly recognized, so far possible also localized and limited. Correspond Appropriate information must therefore be available at the point Are available from which countermeasures, e.g. Legs Repair, to be initiated. Very essential for that The targeted initiation of countermeasures is fixed whether a malfunction due to a fault in the terminal or caused by a fault on the connecting cable is. In addition, however, also means any additional Information about the type of problem causing the fault Mistakes are a very important aid for a quick start  Help.

A signaling of a malfunction to the central Remote station is provided that the transmission line would allow against that only those in Criteria formed in the terminals in the usual way To be available. But with that comes the danger that criteria thus formed are incorrectly used as a verb control criteria or as a message sign inter be pretended, because a clear identification of such information as a fault signaling sign is not possible or only possible with considerable effort. Wei Such a fault signaling would always be then leave when the power supply of the terminal has failed.

A well-known method for determining the interference The cause of the failure is that after the appearance of a Disturbance the remote station with the terminal z. B. in telefo African contact occurs, from there instructions on white tere adjustment measures are transmitted and on this Determined details of the cause of the fault will.

The object of the invention is to eliminate interference in terminals Text communication facilities of a remote station and in one that can be clearly evaluated by the remote station Way to signal, without any significant effort at least between the malfunction of the terminal itself and a distinction between a fault on the connecting line that can. At the same time there should be the possibility options for the formation of the interference signals see that allow evaluation in the remote station can be carried out to limit the Serve to cause the fault. Here he goes Finding that in the terminals diagnostic or  Monitoring devices are provided in the event of a fault a corresponding fault message for ver to provide.

This task is performed according to the in the characterizing part given measures resolved.

One of the advantages of the method according to the invention is its universal applicability. This is essentially based lichen that the flow of normal messages transmission by the errors formed according to the invention signals is influenced as little as the course of the normal connection establishment and disconnection. A Another advantage is the simple generation and Evaluation of the interference proposed according to the invention tion signals, their generation also in the event of failure of the terminal power supply is ensured.

Arrangements for performing the method in systems with direct current or alternating current transmission characterized in the subclaims.

The invention is based on some Ausfüh Rungsbeispiele explained in more detail, while also on other advantages are pointed out. In detail shows

Fig. 1 and Fig. 2 each show an example for performing the method according to the invention, in an operating with direct current double current transmission technology system

Fig. 3 and Fig. 4 each a corresponding example in a system with direct current single current transmission technology and

Fig. 5 shows an example of implementing the invention in an AC transmission system.

The example shown in Fig. 1 is based on the fact that for message transmission between a terminal TE and a connected via the connecting line AL , not shown here VS , z. B. a switching office, a high-level direct current transmission technology with double current is applied. There are only the parts necessary for understanding the invention, namely the transmitting and receiving units S and E of the terminal TE and the devices provided to form a fault signal in the connection part AS of the terminal. Only the two switching transistors are shown in the transmission unit S ; In the receiving unit E , only the light-emitting diodes D 1 and D 2 of the two optocouplers are shown here. The two mutually independent transmission channels, namely the transmission channel with the wires a 1 and b 1 and the reception channel with the wires a 2 and b 2 , allow a fully duplex-capable transmission. The establishment of the connection and the disconnection, as well as the message transmission itself takes place in the manner known for double-current operation. The line stream, which is reversed for sending messages in the rhythm of the telex characters to be sent, is supplied by the sending unit. Via the connecting line AL in the receiving unit E incoming current steps are evaluated according to their polarity and in a manner not shown in the terminal continues to work.

The signaling of a malfunction occurs according to the invention in that the error signals clearly and reliably differ from the criteria provided for normal connection control and for normal message transmission. In the embodiment according to FIG. 1 this is done in such a way that a low-frequency signal is provided as the error signal, the frequency of which is greater than the telegraph frequency, e.g. B. at a telegraph speed of 50 Bd is greater than 150 Hz. This ensures a safe and simple evaluation in the remote station, since this value lies outside the AC fundamental wave that arises when the direct current is sensed and is superimposed on the signal states of the message transmission. As is known, the frequency of this alternating current fundamental wave at 50 Bd has a value which is between 25 Hz and 150 Hz.

To generate the error signal, an AC generator G is provided in the connection part AS of the terminal TE , which is switched on by a signal F 1 when an error occurs in the terminal TE . The switch-on criterion (signal F 1 ) for the generator G is z. B. formed in the self-diagnosis of the terminal, which is either routinely processed in the device, or which is initiated on the basis of a diagnosis sent by the remote station to the terminal. Likewise, the switch-on criterion, namely the signal F 1 in the event of a power failure, can be formed in the terminal. In Fig. 1, the control switching means is realized by a relay F and the switching element by a contact f associated with the sem. In the event of a fault, the relay F is excited from the terminal TE and the generator G is switched on via its contact f . In the exemplary embodiment from FIG. 1, the arrangement of the con tact f is selected such that it is in fault-free condition of the terminal bridging a resistor R switched into the receiving line. If an error occurs, the resistor is looped into the receive line, and the voltage drop across it is used both for switching on and via a rectifier circuit GL for supplying power to the generator G. This arrangement has the advantage that the generator is fully functional regardless of the power supply of the terminal T , so it is fully available to emit an error signal even if the power supply fails.

If, which is within the scope of the invention, the generator is equipped with its own independent power supply, for example in the form of a battery, an accumulator or a storage capacitor, the contact f can only be provided as a switch which connects the generator G to the connecting line AL turns on.

The provided in the embodiment of FIG. 1 generator G is seen before for sending a certain frequency, the z. B. for a telegraph speed of 50 Bd is greater than 150 Hz. However, it is within the scope of the invention to provide a generator G which can emit several un distinguishable frequencies. This possibility offers advantages if various error criteria are available from the terminal device TE , for example ge as part of diagnostic processes. In this case, for example, several control switching means would be provided, via the switching elements of the generator can be controlled in such a way that for each Fehlercri terium a dedicated frequency is sent as an error signal.

Fig. 2 shows an embodiment for the formation of an error signal with a frequency that is less than 25 Hz. This frequency is also outside of the AC fundamental wave that arises during DC scanning and can therefore be known and evaluated safely and easily in the remote station. For generating such error signal in the receiving branch a 2, b 2 provided as the signal ge via a d existing of a resistor R 2, a capacitor C and a through-connection member of so-called relaxation oscillator RO tion. The connection of the Rela xationsoszillators RO in turn is done via a control switching means, in the example via the relay F and its contact f , which is actuated in the event of an error in a manner not shown here by the signal F 1 . The capacitor C is then via the resistor R 2 directly in the receiving branch a 2 , b 2 . After the capacitor C has been charged, the switching element d shorts the line and the discharge of the capacitor C begins. After its discharge, the switching element d opens again and the process described begins anew. In this way, a low-frequency error signal is generated with a frequency that is less than 25 Hz. This error signal is transmitted via the connecting line AL , namely via the receiving branch a 2 , b 2 , to the remote station VS. Since a current monitoring is usually provided in the transmitting circuit of the remote station VS , which corresponds to the receiving circuit of the terminal, this error signal can be easily recognized and evaluated there.

However, it is also possible to transmit such an error signal via the transmission branch, ie via the wires a 1 , a 2 of the connecting line AL to the remote station VS. In this case, coupling into the transmission branch is required, but this is easily possible. In Fig. 2, this possibility has been shown in the form of a dashed transformer coupling K.

The method according to the invention is also advantageously applicable to direct current transmission according to the single current principle. An example of this is shown in Fig. 3 in the event that the error signal with a frequency that is greater than z. B. 150 Hz is formed and transmitted. The terminal TE in turn has a transmitting part S and a receiving part E. In the example, only the transmitting contact sk and the so-called closed-circuit current contact rk are shown in the transmitting part S. When sending messages, the line contact sk , in this case supplied by the remote station VS , is interrupted in the rhythm of the characters to be sent via the send contact sk . In the receiving part E , the current steps and the current pauses are evaluated. The quiescent current contact rk is used in a manner known per se to signal an increase in current, in that it either bridges the resistor R 3 or is switched into the line.

To signal a fault, a generator G is again provided, which is switched on in the event of a fault via the switching element f of the control switching means F and then emits a frequency which, for. B. is greater than 150 Hz. As has already been described with reference to FIG. 1, the power supply to the generator G can be carried out either via a battery or via a storage capacitor. However, a supply from the line current is also advantageous here, with that at the resistor R 4 falling voltage with the interposition of a rectifier circuit GL is used both for switching on and for the power supply of the generator G. By dimensioning the resistor R 4 can also be achieved that a call criterion is signaled when the counterpart is turned on. This is the case when the resistance R 4 is relatively small and therefore a current flows on the line AL in the order of the value provided for the call state, ie this current is generally about 40 mA. In the event that a signal comparable to the call signal is not desired, the resistance R 4 is larger to select. The resistor R 4 can also be looped into the connecting line AL , taking into account the resistance of the R 3 which is parallel to the closed-circuit current contact rk .

Fig. 4 shows an embodiment in which a frequency signal is formed and emitted as an error signal, which is less than 25 Hz. The circuit has as a signal generator in turn consisting of the resistor R 2 , the capacitor C and the switching element d relaxation oscillator RO on. The turn-on takes place again, as already described with reference to FIG. 2, by a signal F 1 , via the control switching means F and its switching element f . The mode of operation corresponds to the mode of operation described with reference to FIG. 2.

The evaluation of the error signals formed in this way takes place in the remote station VS , ie generally in the switching center to which the terminal in question is connected via the connecting line. A particularly simple evaluation option results when using an error signal in the form of a frequency which is lower than the lowest frequency in the telegraph signal before it, that is to say which is smaller than 25 Hz. In this case, this is merely an assessment of the interruption in many cases anyway carry out monitored transmission currents. However, it is always possible to determine with certainty whether there is a fault in the end device or whether the connection line is faulty. In the first case an error signal is always received, in the other case not.

The invention has been explained above for direct current transmission methods. With the same advantages, it can also be used if AC transmission technology is used on the transmission link between a terminal and a remote station. An example of this is shown in FIG. 5. From the terminal TE , only the known transmit-receive converter SEU is shown here, which is connected via the connecting line AL to a counterpart VS not shown in detail here, as a rule to a switching office. A direct current of relatively small size is fed into the connecting line AL . Such a direct current, which is also referred to as the so-called frit current IF and is supplied by the switching center, is often already available. The feeding of the direct current IF can also follow it in the connection part AS of the terminal TE . This is advantageously done via a capacitor C 2 and an inductor L 1 , the high-pass filter, which is a kind of switch in terms of function. If an error occurs in the terminal TE , the control switch tel is excited by the interference criterion (signal F 1 ), in the example the relay F , the switching element arranged in the connection part AS , in the example the contact f , the line interrupts or a resistor R 5 switches on. As a result, the direct current is interrupted in the first case, and the size of the direct current IF is reduced in the second case. Both options can be recognized and evaluated in a very simple manner in the central remote station VS. Error signaling by changing the direct current increases the certainty of determining whether an error has occurred in the terminal or on the line.

In text communication systems, in which such a frit current is not available, in a further embodiment of the invention, it is proposed to provide a direct current source either at the terminal or in the remote station. In the exemplary embodiment according to FIG. 5, such a direct current source GS is entered with dashed lines. Via the switching element f of the control switching means F is turned on, this error occurs on the line, and fed a direct current in the line.

The generation of those formed in the manner described Error signals is possible without any significant effort where at it is ensured that the error signal is neither with a connection control signal still with a message signal can be confused. Still is a very  reliable distinction between an error in the end device and a fault on the connection line possible. In order to can take the measures necessary for a quick reaction can be initiated in a targeted and effective manner.

The error signals are evaluated in the Remote site. As a rule, current monitoring can be used Means serve in the event of a DC fault signal, e.g. B. the so-called Frittstrom, in simple Wei monitor. The necessary facilities can NEN be provided individually, z. B. for a Continuous monitoring of each individual to the remote station closed terminal, or they can each on the Number of switching paths may be limited, e.g. B. then if monitoring only when building a ver binding is carried out. A further reduction in the Effort in the remote station is possible in that an evaluation only when an error occurs takes place and it is determined whether it is the error is an error in the terminal, or whether the connection line is faulty.

Claims (14)

1. A method for signaling faults in terminals of text communication devices, in which the terminals are connected via ei ne connection line to a remote station, preferably with a switching office, and in which the faults are identified by evaluating error signals, characterized in that in Depending on the occurrence of a malfunction in the terminal (TE), error signals are generated which, in the case of a DC transmission provided for message transmission between the terminal (TE) and the remote station (VS), are provided as AC signals, in the case of a message transmission between the terminal (TE) and the opposite station (VS) provided AC transmission are formed as direct current signals and transmitted to the opposite station (VS) via the connecting line (AL) . 2. Arrangement for performing the method according to claim 1, characterized in that the switching means (G, RO, GS) for generating an error signal in the connection part (AS) of the terminal (TE) are arranged and each because of a control switching means (F, f ) are switched on, which evaluates a fault message (F 1 ) of the terminal (TE) . 3. Arrangement according to claim 2 for direct current transmission, characterized in that a generator (G) is provided in the connecting part (AS) of the terminal (TE) , which via the switching element (f) of the control switching means (F) when an error occurs (F 1 ) is switched on in the terminal (TE) ,
and which transmits at least one frequency as an error signal via the transmission branch (a, b or a 1 , b 1 ) of the connecting line (AL) to the remote station (VS) , which is greater than that during normal operation of the terminal (TE) by the AC sampling fundamental AC wave. 4. Arrangement according to claim 2 for direct current transmission, characterized in that in the connecting part (AS) of the terminal (TE) a signal transmitter (RO) is provided, which via the switching element (f) of the control switching means (F) when an error occurs (F 1 ) is switched on in the terminal (TE) ,
and which transmits a frequency as an error signal via the receiving branch (a, b or a 2 , b 2 ) of the connecting line (AL) to the central remote station (VS) , which is smaller than that during normal operation of the terminal (TE) the AC fundamental wave occurring. 5. Arrangement according to claim 4, characterized in that in the case of a duplex-capable transmission of the signal transmitter (RO) in the receiving branch (a 2 , b 2 ) of the connecting line (AL) is arranged and the error signal via the receiving branch (a 2 , b 2 ) reports to the remote site (VS) . 6. Arrangement according to claim 5, characterized in that at the output of the signal transmitter (RO) in the transmission branch (a 1 , b 1 ) of the connecting line (AL) arranged coupling member (K) is connected, via which the error signal in the transmission branch ( a 1 , b 1 ) of the connecting line (AL) is fed. 7. Arrangement according to claim 4 to 6, characterized in that the signal transmitter (RO) is a relaxation oscillator (R 2 , c, d) . 8. Arrangement according to claim 3 to 7, characterized in that the power supply of the generator (G) and the signal generator (RO) is independent of the power supply of the terminal (TE) . 9. Arrangement according to claim 8, characterized in that the power supply of the generator (G) and the Si gnalgebers (RO) each through the in the receiving branch (a, b or a 2 , b 2 ) of the connecting line (AL) flowing and in the opposite line (VS) feeds the line current. 10. The arrangement according to claim 9, characterized in that in the case of a duplex-capable transmission (double current operation) in one wire (a 2 ) of the receiving branch (a 2 , b 2 ) of the connecting line (AL) arranged resistor (R 1 ) by the switching element (f) of the control switching means (F) is turned on and the (1 R) from falling voltage, both the generator (G) turning on the resistor and is used to power the generator (G), and that (in the case of a half-duplex transmission-flow mode ) a between the wires (a, b) of the transmitting and receiving branch of the subscriber line (AL) arranged resistor (R is turned on by the switching element (f) of the control switching means (F) 4) and the voltage dropping at the resistor (R 4) both the voltage generator (G) turns on and provides power to the genera tors (G). 11. The arrangement according to claim 2 for AC transmission, characterized in
that a high-pass filter (C 1 , L 1 ) is arranged in the connecting part (AS) of the terminal (TE) and the switching element (f) of the control switching means (F) is arranged in a wire of the connecting line (AL) in the direction of the connecting line (AL) ,
and that in the event of a fault message ( F 1 ) the value of a direct current (IF) flowing through the connecting line (AL ) is changed. 12. The arrangement according to claim 11, characterized in that the switching element (f) of the control switching means ( F) in the event of a fault message (F 1 ) breaks the direct current (IF) under. 13. The arrangement according to claim 11, characterized in that the switching element (f) of the control switching means ( F), a resistor (R 5 ) is connected in parallel via which, in the event of a fault message (F 1 ), the value of the direct current (IF) is reduced becomes. 14. Arrangement according to claim 11, characterized in that a direct current source (GS) is provided in the connection part (AS) of the terminal (TE) , which in the event of a fault message (F 1 ) by the switching element (f) of the control switching means ( F) is turned on.