DE3407669A1 - Method and circuit arrangement for signalling interference in terminal devices of text communication devices - Google Patents

Abstract

The invention relates to a method for signalling interference which occurs in text terminal devices (TE) to a central distant station (VS); the error signal is formed in the case of DC transmission for normal data transmission as an AC signal and in the case of AC transmission for normal data transmission as a DC signal, in each case in the connection part (AS) of the terminal device (TE) depending on the occurrence of an error (FI) in the terminal device (TE) and is transmitted to the distant station (VS) via the connection line (AL). <IMAGE>

Description

Method and circuit arrangement for signaling

Interference in terminals of text communication devices The invention relates to a method for signaling faults in terminals of text communication devices according to the preamble of claim 1, as well as arrangements for implementation this procedure.

Used to transfer messages between one for text communication intended terminal and a remote station, e.g. between a teleprinter and a central office, via a subscriber line, are different transmission methods known. A basic distinction is made between so-called direct current transmission technology and the so-called alternating current transmission technology. In the first case you can choose between a so-called double-stream and a so-called. Simple current transmission technology separate. With the double stream method, the transmission of messages takes place through Polarity reversal of a direct current flowing on the connecting line takes place. With the single stream method the messages are sent by sensing the direct current flowing on the connecting line transfer. Since the direct current has a relatively high value in these cases, e.g. a Has a value of 40mA, it is also referred to as direct current high-level transmission technology. The use of the double-stream or the single-stream process depends on the circumstances of the existing network and the requirements that are made in detail. For example, two independent transmission channels are used for duplex transmission the Double stream method used, while for a half-duplex transmission The single-stream method can usually be used over only one channel.

The alternating current transmission technology, in which with a lower Level is worked, and therefore often as low level alternating current transmission technology always represents a duplex-capable system. The transmission principle is here that in both directions, so in the direction from the terminal to Remote station and from the remote station to the terminal each with a different carrier frequency is being worked on.

Regardless of the type of transmission technology used the requirement for secure message transmission is an urgent priority a. Although the devices currently in use are especially reliable in terms of reliability and functionality meet high requirements, but malfunctions cannot be excluded.

It should be noted that interference is not only caused by errors in the terminal, but also due to errors on the transmission path, i.e. on the connecting line can be caused. In any case, a quick reaction is always required. For this, however, it is again a prerequisite that the cause of the fault is identified quickly, is localized and limited as far as possible. Corresponding information must therefore be available at the point from which countermeasures, e.g. a repair can be initiated. Quite essential for the targeted introduction One of countermeasures is the determination of whether a fault is caused by an error in the terminal or is caused by a fault on the connection line. In addition, means but also any additional information about the type of triggering the disturbance Error is a very important help for a quick turnaround help.

A signaling of a fault to the central remote station is, provided the transmission line would allow, contrary to that only those criteria that are normally formed in the terminals are available for this purpose stand. However, this involves the risk that criteria formed in this way are incorrect are interpreted as connection control criteria or as message characters, because such information is unambiguously identified as a fault signaling symbol is not possible or only possible with considerable effort. Furthermore would such a Fault signaling is always ruled out when the power supply to the terminal device has failed.

A well-known method for determining the cause of the problem consists in the fact that after the occurrence of a fault, the remote station with the terminal E.g. enters into telephone contact, from there instructions on further setting measures and in this way details of the cause of the fault can be determined will.

The object of the invention is to eliminate interference in terminals of text communication devices one remote station and in one that can be clearly evaluated by the remote station Way to signal, with little effort at least between the Disturbance of the terminal itself and a disturbance on the connection line can be. At the same time there should be the possibility for the formation of the disturbance signals Provide options that allow evaluations to be carried out in the remote station can be used to isolate the fault causing the fault. Included the invention assumes that in the terminals diagnostic or Monitoring devices are provided that in the Fs of an error a corresponding error message Provide.

This task is carried out according to the measures specified in the identifying part geiöst.

One of the advantages of the method according to the invention is that it is universal Applicability. This is based essentially on the fact that the course of the normal Message transmission through the error signals formed according to the invention as well It has little influence on the normal course of connection establishment and disconnection. Another advantage is the simple generation and evaluation of the the invention proposed disturbance signals, their generation also in the event of failure the end device's own power supply is ensured.

Arrangements for carrying out the process in systems with direct current or, i? it AC transmission are characterized in the subclaims.

The invention is illustrated below with the aid of some exemplary embodiments explained in more detail, with reference to other advantages at the same time. In detail Fig. 1 and Fig. 2 each show an example for carrying out the invention Process in a working with direct current double current transmission technology Plant, FIGS. 3 and 4 each show a corresponding example in a plant with direct current single current transmission technology and FIG. 5 shows an example for carrying out the invention in an AC transmission working plant.

The example shown in Fig. 1 is based on the fact that for message transmission between a terminal TE and one connected via the connecting line AL, Remote station VS, not shown here, e.g. a switching office, a High level direct current transmission technology with double current is applied. There are shown here only the parts necessary to understand the invention, namely the sending and receiving units S and E of the terminal TE and the formation a fault signal provided devices in the connector AS of the terminal. In the transmission unit 5, only the two switching transistors are shown; in the receiving unit E are of the two optocouplers, here only their light-emitting diodes D1 and D2 shown. The two independent transmission channels, namely the transmission channel with the wires al and bl and the receiving channel with the wires a2 and b2, allow full duplex transmission. The connection establishment and the The connection disconnection and the message transmission itself are carried out for double-flow operation known way. The line current used to send messages in rhythm the polarity of the telex characters to be transmitted is reversed by the transmitter unit delivered. Current steps arriving in the receiving unit E via the connecting line AL are evaluated according to their polarity and in a manner not shown here further processed in the end device.

The signaling of a fault occurs according to the invention in that the error signals are clearly and reliably different from those for a normal Connection control and criteria provided for normal message transmission differentiate. In the embodiment according to Fig.

1 this is done in such a way that the error signal is a low frequency Signal is provided, its frequency is greater than the telegraph frequency, e.g. at a telegraphing speed of 50Bd is greater than lSOHz.

This enables a safe and simple evaluation in the remote station ensured, since this value is outside the range that occurs when the direct current is sampled and the signal states of the message transmission superimposed alternating current fundamental wave lies. The frequency of this alternating current fundamental wave is known to be at 50Bd Value between 25Hz and 1TOHz.

To generate the error signal is in the connection part AS of the terminal TE an alternating current generator G is provided which, if a fault occurs in the terminal TE is switched on by a signal F1. The switch-on criterion (signal F1) for the generator G is formed e.g. during the self-diagnosis of the terminal, which either routinely processed in the device, or on the basis of one from the remote station the diagnostic command sent to the terminal is triggered. The switch-on criterion can also be namely, the signal F1 can be generated in the terminal in the event of a power failure. In Fig. 1 is the control switching means by a relay F and the switching element by one of these assigned contact f realized. In the event of a fault, the relay F is switched off by the terminal TE is excited off and the generator G is switched on via its contact f. In the exemplary embodiment According to Fig. 1, the arrangement of the contact f is chosen such that it is in error-free State of the terminal a resistor R connected to the receiving line is bridged. If an error occurs, the resistor is looped into the receiving line, and the voltage drop falling across it serves 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 independent of the power supply of the terminal T is fully functional, even if the power supply fails to the Output of an error signal is fully available.

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

The generator G provided in the exemplary embodiment according to FIG. 1 is intended for the transmission of a certain frequency, e.g. for a telegraph speed of 50Bd is greater than 150Hz. However, a generator is within the scope of the invention G to be provided, which can emit several distinguishable frequencies. This possibility offers advantages when the terminal TE is different, for example in the frame Error criteria formed by diagnostic processes are available. In this Case would be provided, for example, a plurality of control switching means over which Switching elements of the generator can be controlled in such a way that for each error criterion a dedicated frequency is sent out as an error signal.

Fig. 2 shows an embodiment for forming an error signal with a frequency that is less than 25Hz. This frequency is also outside the alternating current fundamental wave that arises during direct current keying and can thus can be safely and easily recognized and evaluated in the remote station. To the generation such an error signal is in the receiving branch a2, b2, as a signal transmitter on off a resistor R2, a capacitor C and a through-connection element d existing so-called relaxation oscillator R0 is provided. The connection of the relaxation oscillator R0 takes place again via a control switching means, in the example via the relay F and its Contact f, that in the absence of it does not fall closer here is actuated in the manner shown by the signal F1. The capacitor C is then via the resistor R2 directly in the receiving branch a2, b2. After charging the capacitor C the switching element d shorts the line and the discharge of the capacitor C starts. After its discharge, the through-connection element d opens again and the one described The process begins again. This creates a low frequency error signal generated at a frequency that is less than 25Hz. This error signal is over the connecting line AL and that via the Emp receiving branch a2, b2, to the remote station VS transmitted. Since in the sending circuit of the remote station VS, which is the receiving circuit of the terminal corresponds, as a rule, a current monitoring is provided, this error signal can can be recognized and evaluated there without further ado.

However, it is also possible to send such an error signal via the transmission branch, i.e. to be transmitted via the wires a1, a2 of the connection 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 is shown in dashed lines registered. transformer coupling K has been shown.

The method according to the invention is also suitable for direct current transmission can be used advantageously according to the single-stream principle. An example of this is shown in Fig. 3 in the event that the error signal has a frequency which is greater than e.g. 150Hz is formed and sent out. The terminal TE in turn has a transmission part S and a receiving part E. In the example, only the send contact is in the send part S sk, and the so-called closed-circuit contact rk is shown. When sending messages is sent via the send contact sk, in this case from the opposite Job VS supplied line current interrupted in the rhythm of the characters to be sent. In the receiving part E, the current steps and the current pauses are evaluated.

The closed-circuit current contact rk is used for signaling in a manner known per se an increase in current by the resistor R3 either bridged by it or is switched on in the line.

A generator G is again provided to signal a fault, which is switched on via the switching element f of the control switching means F in the event of a fault and then emits a frequency that is e.g. greater than 150Hz. As already Was described with reference to Fig. 1, the power supply of the generator G can either take place via a battery or a storage capacitor. Is beneficial However, here, too, a supply from the line current, with the one at the resistor R4 falling voltage with the interposition of a rectifier circuit GL both for switching on as well as for powering the generator G is used. By dimensioning the resistor R4 it can also be achieved that when it is switched on, a call criterion is signaled to the remote station. That is the case when the resistor R4 is relatively small and on the line AL therefore a current in the order of magnitude of that provided for the call state Value flows, i.e.

that this current is usually around 40mA. In case that a signal comparable to the call signal is not desired, is the resistance Choose R4 larger. The resistor R4 can also take into account the dem Quiescent current contact rk parallel resistor R3 in the connecting line AL be looped in.

Fig. 4 shows an embodiment in which the error signal is a Frequency is formed and sent out, which is less than 25Hz. The circuit points as a signaling device again one from the resistor R2, the Capacitor C and the circuit element d existing relaxation oscillator R0. The activation takes place again, as already described with reference to FIG. 2, by a signal F1, via the control switching means F and its switching element f.

The mode of action corresponds to the mode of action described with reference to FIG.

The error signals formed in this way are evaluated in each case in the remote station VS, i.e. usually in the exchange to the the terminal in question is connected via the connecting line. One special simple evaluation option results when using an error signal in form a frequency that is lower than the lowest occurring in the telegraph signal Frequency, i.e. which is less than 25Hz. In this case there is only an evaluation the interruption of the transmission, which in many cases is monitored anyway. However, it is always possible to determine with certainty whether there is a malfunction there is an error in the terminal or whether the connection line is disturbed. In the first case an error signal is always received, in the other case not.

The invention has been described above for direct current transmission processes explained. With the same advantages, however, it can also be used when on the transmission path between a terminal and a remote station uses AC transmission technology is applied. An example of this is shown in FIG. 5. The terminal TE is only here the per se known transmit / receive converter SEU is shown, which over the connecting line AL with a remote station VS, not shown in detail here, usually with an exchange, is connected. A direct current is fed into the connecting line AL relatively small size fed. Often there is one even Direct current referred to as the so-called Frittstrom IF, that from the exchange is already available. The feed of the direct current IF can but also take place in the connection part AS of the terminal TE. Advantageously happens via a high-pass filter consisting of a capacitor C2 and an inductance L1, which is functionally a kind of switch. When an error occurs in the end device TE becomes the control switching means through the disturbance criterion (signal F1), in the example the relay F is energized, its switching element arranged in the connection part AS, in the example the contact f interrupts the line or switches on a resistor R5. Through this in the first case the direct current is interrupted, in the second case the direct current is interrupted IF reduced in size. Both ways can be done in a very simple way can be recognized and evaluated in the central remote station VS. An error signaling by changing the direct current increases the certainty of determining whether a An error has occurred in the end device or on the line.

In text communication systems in which such a frittstrom is not is available, is proposed in a further embodiment of the invention, 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 shown in dashed lines has been registered. Via the switching element f of the control switching means F this is connected to the line in the event of a fault and a direct current fed into the line.

The generation of the error signals formed in the manner described is possible without significant effort, whereby it is ensured that the error signal confused neither with a call control signal nor with a message signal can be. Still, one is very sure distinction between an error in the terminal and a fault on the connection line possible. In order to can take the measures necessary for a quick response in a targeted and effective manner be initiated.

The evaluation of the error finals takes place in the remote station. As a rule, current monitoring devices can be used for this purpose, which in the event of a direct current error signal, for example, monitor the so-called fritting current in a simple manner. The facilities required for this can be provided individually for each subscriber, e.g. for permanent monitoring of each individual terminal connected to the remote station, or they can be limited to the number of through-connection paths, e.g. if monitoring is only carried out when a connection is established. A further reduction of the effort in the remote station is possible in that an evaluation only takes place when an error occurs and it is determined whether the error is an error in the terminal or whether the connection line is disturbed.

Claims (14)

Method for signaling faults in terminals of text communication devices that are connected to a remote station via a connection line, preferably connected to an exchange, characterized in that that depending on the occurrence of a fault in the terminal (TE) generates error signals that in the case of a message transmission between the terminal (TE) and the remote station (VS) provided direct current transmission as alternating current signals, in the case of a message transmission between the terminal (TE) and the remote station (VS) provided alternating current transmission formed as direct current signals and via the connection line (AL) are transmitted to the remote station (VS), and that in the Remote station (VS) at least determined by evaluating the error signals whether the terminal (TE) or the connecting line (AL) is disturbed. 2. Arrangement for performing the method according to claim 1, d a it is indicated that the switching means (G, RO, GS) are used to generate an error signal are arranged in the connection part (AS) of the terminal (TE) and be switched on via a control switching means (F, f), which sends a fault message (F1) of the terminal (TE) evaluated. 3. Arrangement according to claim 2 for direct current transmission, characterized characterized in that a generator (G) is provided in the connection part (AS) of the terminal (TE) is that via the switching element (f) of the control switching means (F) when a Error (F1) is switched on in the terminal (TE), and that as an error signal at least one frequency over the transmission branch (a, b or al, bl) of the connection line (AL) sends out to the remote station (VS), which is larger than that during normal operation of the terminal device (TE) due to the direct current keying occurring alternating current fundamental wave. 4. Arrangement according to claim 2 for direct current transmission, characterized in that that a signal transmitter (RO) is provided in the connection part (AS) of the terminal (TE), via the switching element (f) of the control switching means (F) when an error occurs (Fl) is switched on in the terminal (TE), and the error signal is a frequency Via the receiving branch (a, b or a2, b2) of the connection line (AL) to the central Remote station (VS) sends out, which is smaller than that during normal operation of the terminal (TE) alternating current fundamental wave generated by direct current sampling. 5. Arrangement according to claim 4, d a d u r c h g e k e n n z e i c h n e t, that in the case of a duplex-capable transmission, the signal transmitter (RO) in the receiving branch (a2, b2) of the connecting line (AL) is arranged and the error signal via the receiving branch (a2, b2) reports to the remote station (VS). 6. Arrangement according to claim 5, d a d u r c h g e k e n n z e i c h n e t that at the output of the signal generator (RO) a in the transmission branch (al, bl) the Connection line (AL) arranged coupling member (K) is connected via the the error signal is fed into the transmission branch (al, bl) of the connecting line (AL) will. 7. Arrangement according to claim 4 to 6, d a d u r c h g e k e n n z e i c h n e t that the signal generator (RO) is a relaxation oscillator (R2, c, d). 8. Arrangement according to claim 3 to 7, d a d u r c h g e k e n n z e i c h n e t 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 signal generator (R0) each through the in the receiving branch (a, b or a2, b2) of the connecting line (AL) flowing and in the remote station (VS) fed-in line current takes place. 10. The arrangement according to claim 9, characterized in that in the event a duplex-capable transmission (double current operation) one in one wire (a2) of the Receiving branch (a2, b2) of the connecting line (AL) arranged resistor (R1) through the switching element (f) of the control switching means (F) is switched on and the Resistance (Rl) falling voltage both switches on the generator (G) and serves to power the generator (G), and that in the case of a half-duplex capable Transmission (single current operation) between the wires (a, b) of the send and receive branches the connection line (AL) arranged resistor (R4) through the switching element (f) of the control switching means (F) is switched on and the one falling across the resistor (R4) Voltage both switches on the generator (G) and supplies power to the generator (G) serves. 11. Arrangement according to claim 2 for alternating current transmission, characterized characterized in that in the connection part (AS) of the terminal (TE) a high-pass filter (Cl, Ll) and in the direction of the connecting line (AL) the switching element (f) of the control switching means (F) is arranged in a wire of the connecting line (AL), and that in the case of a Fault message (Fl) the value of a direct current flowing over the connecting line (AL) (IF) is changed. 12. The arrangement according to claim 11, d a d u r c h g e k e n n z e i c h n e t that the switching element (f) of the control switching means (F) in the event of a fault message (F1) interrupts the direct current (IF). 13. Arrangement according to claim 11, characterized in that the switching element (F) of the control switching means (F) a resistor (R5) is connected in parallel via which reduces the value of the direct current (IF) in the event of a fault message (Fl) will. 14. Arrangement according to claim 11, characterized in that in the connecting part (AS) of the terminal (TE) a direct current source (GS) is provided, which in the case a fault message (F1) by the switching element (f) of the control switching means (F) is switched on.