DE1214739B - Method for recognizing signal signs on connecting lines in telecommunication systems, in particular telephone systems - Google Patents

Description

Method for recognizing signal signs on connecting lines in telecommunication systems, in particular telephone systems. It is already known to monitor telecommunication lines for their respective state, i.e. H. on whether the loop is open or closed, assigned to the individual telecommunication lines ferromagnetic or ferroelectric means However, depending on the prevailing state of each loop occupy one or the other of the two possible stable states. These ferromagnetic or ferroelectric means are periodically applied with scanning pulses which, depending on their polarity, bring about a change of state in the presence of one or the other state and thereby generate control pulses in an output line which indicate one of the two line states.

In addition to determining the free and busy status of telecommunication lines such arrangements are also for the detection of communication lines number wheel pulses sent, which have a brief repeated loop interruption are suitable if, on the other hand, it is ensured that the dial selection any changes in state that occur can be reliably detected. So it has to be at least a sampling pulse with the number disc pulse itself and at least one sampling pulse coincide with the subsequent pause. The end of a series of impulses and the Activation of a telecommunication line can be made from the pulse pauses or the number disc pulses even in a simple manner by counting those indicating the same line status Query results can be averaged. Due to the specified duration of the dial pulses and the subsequent pauses result from a given pulse repetition time for the sampling pulses a maximum number of similar successive ones Query results for the identification of a dial pulse and the subsequent Pulse pause. In contrast, a larger number of consecutive similar If query results are determined, either the end of a series of current impulses is present, or the connection was terminated.

The aforementioned method can also be used in Systems are possible in which, instead of number disk pulses, signal characters in Form of DC or AC code characters are transmitted, which respectively A short-term loop current reduction precedes the connection of a corresponding Receiving device controls on the connection line. Since the DC or Alternating current code characters introducing loop current drops or interruptions are of much shorter duration than the dial pulses, the scanning would have to occur correspondingly more frequently than when recognizing number disk pulses.

Following on from the last-mentioned possibility, the present invention also relates to a method for recognizing signal signs on connecting lines in telecommunications, in particular telephone systems, in which the connecting lines are checked for their state by means of ferromagnetic or ferroelectric means that are individually assigned and periodically queried and have two stable states (Loop open or closed) -monitored and in which signal characters are transmitted in the form of direct current or alternating current code characters, each of which is preceded by a brief loop current reduction or interruption, which controls the connection of a corresponding receiving device to the connection line. The object of the method according to the invention is to enable, without additional effort, the recognition of the signs introducing the direct current or alternating current code characters under approximately equally favorable scanning conditions as are given with dial pulses. This is achieved in that the bistable means assigned to the individual connecting lines are under a permanently effective influence, which is sufficient both when the subscriber loop is open and when the loop current is reduced for a short time as a result of the preliminary signal introducing the individual code characters, to switch the bistable means to the currentless line state and to transfer the state that lasts until the next interrogation time, and that the continuation of the state assumed due to the change of state occurring at the beginning of each scanning process after the scanning process has ended is evaluated as an activation criterion for the code character receiving device. In contrast to the known method, the method on which the invention is based also uses the storage effect of the ferromagnetic or ferroelectric means individually assigned to the individual lines, in that a transition from the state corresponding to the open subscriber loop to the state corresponding to the closed loop is only possible in conjunction with a scanning pulse is. The influence exerted on the line-specific means by the current flowing when the loop is closed is therefore not sufficient on its own to bring about a change in state. This is only possible under the additional influence of the subsequent scanning pulse. As a result, loop current reductions or interruptions can still be reliably detected if no sampling pulse coincides with the loop current reduction or interruption, since the state of the line-specific device caused by the loop current reduction or interruption remains stored until the next query time. The result is that the sampling period can be chosen to be significantly larger than the duration of the distant signal. An upper limit is only set by the fact that, after the connection criterion for the code character receiving device has been determined, the remaining evaluation time must be sufficient to be able to reliably evaluate the transmitted code character. Since the code characters have approximately the same length as the number disk pulses and, on the other hand, since the evaluation time can be kept short compared to the length of these characters, the scanning conditions are approximately the same as for number disk pulses.

In addition, the distinction between the free state (subscriber loop open) from the busy state (subscriber loop closed) in a simpler way Way possible, - that when the free state is present with each scanning process one two changes of state of the line-specific means is connected, of which the first by the influence of the sampling pulse itself and the second after Decay of the sampling pulse. is effected by the constantly effective influence, while when the busy state is present. apart from the first change of state after changing the line status, no further status changes occur. By the- distinction between the once. and the double occurring change of state with a scanning process is therefore a clear criterion for the connection given by the code character receiver.

Incorrect connections of the code character receiving device, through the. Transition from the idle to the busy state of a line triggered can be avoided in a simple manner that only after the presence the busy state. Occurring one-time state changes with each scanning process as a switch-on criterion. get ranked. This distinction is without additional Effort possible, since the query results determined during each scanning process are normally used are stored in line-specific storage elements so as to make changes Recognize the line status immediately and from this the necessary control commands to be able to derive. However, there is a risk that a Vorsigrigl will not be recognized when the interrogation pulse coincides with the distant signal. This disadvantage leaves but bypass according to a further embodiment of the invention in that an established one-time change of state of the queried line-specific means only then is rated as an activation criterion if the last or penultimate Interrogation process has been determined that the line-individual means was in the state corresponding to the current-carrying line state.

Further details of the invention are explained in more detail below with reference to an exemplary embodiment which is shown in the drawings. In detail, Fig. 1 shows a schematic representation of an arrangement for carrying out the method on which the invention is based, FIG. 2 the hysteresis loop of a ferromagnetic toroidal core used as a line-specific means, and FIG. 3 is a timing diagram for explaining the scanning conditions.

F i g. 1 shows in its upper part the telecommunication line VL with the subscriber station Tln and the line-specific means K for monitoring the line status, which is linked to the telecommunication line via the two control windings Wsl and Ws2. A permanent pre-magnetization is effective via the winding Wv, while sampling pulses are periodically supplied to the sampling winding Wa. The control pulses induced in the winding WI with each change of state of the line-specific means K designed as a ring core are fed via the read amplifier LV to the evaluation logic AL, which is expediently part of the central register Reg. A connecting unit D shown is connectable via the control of the central register Reg, the code mark receiving device CE to the individual connecting lines VL - is still. The memory for the storage of the individual query results is designated by SP. The control of the line-specific memory bits in the memory SP and the line-specific means K takes place synchronously by the scanning device AB, which is shown schematically as a voter with three synchronously running voter arms L, A and E , of which the voter arm L controls the line-specific means K, the voter arm A is used to store the information contained in the associated memory bits and the voter arm E to store the new information.

However, before the operation of the arrangement according to FIG. 1 is explained in conjunction with one another, first refer to FIG. 2 and 3, reference is made and the scanning conditions. discussed. F i g. 2 shows the hysteresis loop of a ferromagnetic ring core as a line-specific means, which also applies in an analogous manner to a ferroelectric means. In the idle state, i. H. when the subscriber loop is open, the toroid is located. Due to the constantly effective influence Hv through the pre-excitation winding Wv in the magnetization state-A on the negative saturation branch -p of the hysteresis loop. If the toroidal core is now supplied with an interrogation pulse via the W # ck # winding Wa, the toroidal core is remagnetized due to the influence Ha for the duration of the interrogation pulse and transferred to the magnetization state X on the positive saturation branch + p of the hysteresis loop. During this magnetization reversal process, for example, a positive pulse is induced in the output winding WI. After Ab "of the sampling pulse sound the ring core under the sändigen influence Hv is re-magnetized again and transferred to the initial magnetization state A, again, a control pulse is induced in opposite to the first control pulse polarity in the Ausgabewicklüng WI This last triggered Steueriffipuls represents the actual criterion for the If, on the other hand, the connection line VL is switched to the occupied state by removing the handset from the station Tln, the additional influence Hs of the control windings Wsl and Ws2 almost compensates for the constantly effective influence Hv and the operating point A in the negative remanence -. shifted Br the toroidal core is converted so do not immediately positive to the busy status characteristic, saturation the necessary magnetization reversal takes place only upon the effectiveness of the subsequent probe pulse under the influence Ha. , which results in a transition to the magnetization state X '. In contrast to the free state, there is no further remagnetization after the interrogation pulse has decayed. Each subsequent interrogation pulse only results in a change in the magnetization state along the positive saturation branch + p of the hysteresis loop. If, starting from the occupied state of the connection line VL, the influence of Hs is temporarily suppressed as a result of a loop current reduction or interruption, the magnet core is remagnetised and assumes the initial magnetisation state A for the duration of the loop current reduction or interruption. 'After the loop interruption has ended the working point shifts to the point -Br under the influence of Hs again. This state is maintained until the next interrogation pulse takes effect and magnetizes the toroid again.

So that is the point in time. of each query process a clear statement about the current power state # possible: If the magnetization is reversed from the positive saturation state to the negative saturation state and if a negative pulse is induced in the control winding WI, then the free state is given. If, on the other hand, such a reversal of magnetization does not take place and consequently no control pulse is induced in the control winding WI, then it is. the occupied status. given. In connection with the latter feature is a. Transferring the line-specific mean from the negative. in the: positive saturation state only possible with the transition from vacant to occupied state or as a result of an advance signal announcing a code character in the form of a loop current reduction or interruption, whether the latter is actually present ... can be determined in a simple manner according to the load-look principle in which the last or the last two query results are temporarily stored until the subsequent query result is available and compared with the newly obtained query result.

F i g. 3- shows a: Pulse diagram to explain the scanning conditions. In detail, the Ini-PUISZU9- iVL show the time course of the loop current. on the connecting line T71 at the time of a, code character, consisting of the, pre-signal: Y and # the actual code character: S, the pulse trains 14 the temporal position of the interrogation winding-Wa supplied, dib pulse trains K the state progression of the individual. Means K and the pulse trains iL the induced in the control winding W. 1 : Control pulses, the pulses of polarity 1 at the beginning of each interrogation process at the transition from the negative to the positive saturation state and the pulses. the polarity 2 after completion of the interrogation pulse sound at the transition from; positive to be triggered into the negative state of saturation. The last-mentioned # three pulse trains are each combined into a group and are shown for three different phase positions 1, 11- and III, based on the code signal to be monitored.

Based on the occupied status of the connection line to be monitored (line loop closed). - the line-specific mean-K is in the positive saturation state + p. The interrogation pulsesec or b occurring at this point in time do not cause a complete reversal of magnetization of the individual line. Means, so that only disturbing pulses of low amplitude which remain without effect are induced in the control winding WI. With the beginning of T, the code signaling, the line-specific means K are transferred from the positive saturation state- + p to the negative saturation state # -p as a result of the short-term loop current lowering or interruption that forms the preliminary signal. This state is maintained until the first subsequent interrogation pulse a remagnetizes the line-specific means again and consequently a control pulse of polarity 1 is induced in the control winding W1. The same applies to Example III with the difference that the second interrogation pulse b shown already causes the reset.

In contrast to the two examples 1 and 111, example II shows the case where an interrogation pulse coincides with the distant signal 17 . In this case, the line-specific means K is magnetized twice, so that both a control pulse of polarity 1 and a control pulse of polarity 2 are successively induced in the control winding Wl-. After completion of the interrogation process, the interrogation switching means K remains in the negative saturation state -p, which only occurs with the subsequent one. Interrogation pulse a is finally canceled again, a control pulse of polarity 1 being generated again.

If you now compare the through. the different phase positions of the scanning pulses caused different result sequences with each other, so it follows that in each case the query result "control pulse of polarity 1 - no control pulse of polarity 2" is given. Since such a query result may also indicate the initial transition from the free-in the busy state of the connecting line, which is in Example II imitated in that the interrogation pulse b like everything together with the distant signal V, a comparison with the previous query results is required. If one were to use the fact that no control pulse of polarity 2 was present in the previous query result as a sign that the occupied state is given, then in Examples I and 111 an unambiguous detection of the distant signal would be possible. With regard to Example II, i. H. however, in all cases in which an interrogation pulse coincides with the distant signal V, the distant signal would not be recognized. In order to be able to determine an unambiguous connection criterion in this case as well, the two penultimate query results of polarity 2 would have to be used for comparison. If one assumes that the IMPUlSfOlgeZeit tFb "" of the sampling pulses is greater than the duration of the distant signal V and thus a maximum of only one sampling pulse can coincide with the distant signal V, then a distant signal for connecting the code symbol receiver is definitely present if at least at the occupancy status was present in one of the two last but one query processes, d. H. no control pulse of polarity 2 has occurred. To determine a connection criterion, the query results of three consecutive query pulses, for. B. the interrogation pulses c, b and a or c, b ' and d, required. The evaluation logic AL of FIG. 1 invoice. Accordingly, evaluation logic AL has two information inputs a 1 and a 2, which are connected to the outputs of the sense amplifier LV, wherein the input of a 1, the control pulses of the polarity 1 and the input of a 2, the control pulses of the polarity 2 are fed. and - two further information inputs b and c are fed synchronously with the scanning of the individual Femmeldeleitungen the temporarily stored in the memory SP query results of the two penultimate scans. Only the control pulses of polarity 2 are saved, as these alone are sufficient to identify the free or occupied state of a connection line. All information inputs of the evaluation logic AL are connected to a binary buffer memory Pl or P2 or Pb or Pc. This short-term intermediate storage is necessary because the control pulses do not occur simultaneously via the input signal lines a1 and a2. The SperrgatterS2 program checks to see whether the two were carried out interrogations -zuletzt ever a loop current reduction or - -unterbredhung is done, while the SperrgatterS3 analyzed the same way in the two previous query results. Depending on the result of the blocking gate S 3 and the input signal for the information line a 1, the coincidence gate G continues to check whether the loop interruption determined by the blocking gate S3 has continued. The outputs of the coincidence gate G and the blocking gate S2 are connected via a co-gate M to the signal output of the blocking gate SI, the control input of which is linked to the information input a2 via the buffer memory P2. This blocking gate monitors whether the change in state indicated via the signal input al has been retained after the sampling pulse has decayed. If the latter is the case, a control signal for the register Reg appears at the output of the locking gate SI, which, in a manner known per se, sets the interface device D to the requesting connection line VL, depending on the setting of the scanning device AB, and uses this to couple the central code character receiving device CE to the connection line .

In parallel with the setting of the connection device D , the new query results to be stored in the memory SP are fed to the memory SP via the selector arm E of the scanning device AB. This shifts the ranking of the query results. The previous penultimate query result b becomes the new third from last query result c ', and the hitherto last query result a2 becomes the new penultimate query result b'. At the same time as the new query results are saved, the binary buffer memories P ... are deleted again and are therefore available for the next query results. Finally, it should be pointed out that it is expedient to clock the blocking gate S1 through the scanning device AB in order to create unambiguous test times.

The maximum permissible pulse repetition times for the scanning pulses result from the following consideration: An effective detection of a distant signal for connecting the code character receiving device is only possible after the distant signal has ended. On the other hand, the minimum duration t ".. 1" for the connection of the code character receiving device CE must not be exceeded, so that a reliable evaluation of the transmitted code character is guaranteed. If one also calculates the time t.1-max> the maximum that can elapse until the central code character receiving device has been switched on, then with a minimum duration of to_, the following maximum pulse train time results for the code character, which must not be exceeded: tFab-max = tCE - (ts-max + ta-mi.).

Claims (2)

Claims: 1. A method for recognizing signal signs on connecting lines in telecommunication systems, in particular telephone systems, in which the connecting lines are monitored for their state (loop open or closed) by means of individually assigned Cr and periodically queried and two stable states having ferromagnetic or ferroelectric means and in which signal characters are transmitted in the form of dc or Wechselstroracodezeichen, each preceded by a short-term loop current reduction or interruption, which controls the connection of a corresponding receiving device on the connecting line, d a d u rch g e k s n - is characterized in that the the bistable NutteI (K) assigned to the individual connecting lines are under a permanently effective influence (-Hv) which occurs both when the subscriber loop is open and when the loop current is reduced or interrupted for a short time as a result of the individual code characters hen initiating pre-signal (V) is sufficient to transfer the bistable means (K) into the state (-p) corresponding to the currentless line state and lasting until the next interrogation time, and that the continuation of the state change assumed at the beginning of each scanning process State (+ p) after completion of the scanning process is evaluated as an activation criterion for the code character receiving device (CE). 2. The method according to claim 1, characterized in that the code character receiving device (CE) can only be connected to the connecting lines (VL) if it has been determined in the last or penultimate query process (b or c) that the line-specific means (K ) has found the state (+ p) corresponding to the current-carrying line state. 3. The method according to claim 1 or 2, characterized in that as an indicator for the presence of the currentless line state corresponding state (-p) with the change in state occurring at the end of an interrogation process as a result of the continuously effective influence (-Hv) associated useful signal (2 ) is rated. 4. The method according to claim 3, characterized in that the different polarity of the useful signals (1, 2) associated with the state changes in different directions is evaluated as a distinguishing feature. 5. The method according spoke 2, 3 and 4, characterized in that the query results indicating the line status of the respective last two query processes (b and c) are temporarily stored and that the connection criterion for the code character receiving device (CE) according to the load look Principle is determined.