NO136814B - PROCEDURES FOR TESTING FOURTH} DESCUSSIONS BETWEEN TWO CONNECTION POINTS TO BE CONNECTED WITH EACH OTHER IN A REMOTE COMMUNICATION NETWORK. - Google Patents

Abstract

Procedure for testing four-wire connections between two connection points to be connected to each other in a telecommunications network.

Description

The present invention relates to a method for testing four-wire connections between two connection points to be connected to each other in a centrally controlled telecommunications network with end-to-end path increase, with regard to through-connections ordered by control devices, and noise-free transmission of digital signals, as well as an application of this method in time-sharing telecommunications networks.

In the following, connection points shall mean those bodies

in a remote messaging network in which the individual transmission channels in a first group can be connected to transmission channels in another group or at least to the respective corresponding transmission channel for the opposite direction of transmission. Furthermore, transmission points shall be understood to mean those bodies in a remote message network in which the individual transmission channels can be connected to arbitrary other transmission channels as well as to the respective corresponding transmission channel for the opposite transmission direction. In time-sharing telecommunications networks, a transmission channel must always be understood as a time-sharing channel. A selector unit records selection information and forwards it to a control device or transmits selection information to switching points on command from a control device.

Devices are known from German patent document no. 1 064 552

to test the transmission properties of telegraph lines where a test signal is sent from one station which returns again from the called station. To compare sent and returned

received signs for error checking, there is a warehouse located at the transmitter location,

where the transmitted character is stored until it is compared with

the character sent back from the receiving location. In the absence of a recurring test signal, switching means come into effect in the sending location which initiates a switching action corresponding to the respective operating state. As a telegraph line is tested at all times from its end stations, there must obviously be a test signal transmitter and a test signal decipherer in each station.

From German explanatory document 1 168 506 there is also known a device where the sample character is sent out in one voice channel of a four-wire connection and in the called station is transmitted on the other voice channel to be sent back to the original exchange.

Furthermore, there are known switching devices where a monitoring signal is entered on the line at one end, transformed at the other end by a special device according to the remote signaling system's requirements, and sent back again to the original central office over the same line. In this connection, the monitoring sign can be a special pulse that serves for line monitoring, or also a sign that has already fulfilled a task in the remote signaling system in question, e.g.

a coating pulse or an acknowledgment pulse. In systems with four-wire operation, the transmission of speech and characters is only possible in one direction, because the connected amplifiers block in the opposite direction. For that reason, the monitoring signal is transferred from one voice channel to the other to be sent back to the original exchange.

For the invention, there is the task of giving instructions

in a method by which it is possible in a centrally controlled remote message relay network with a minimal number of test devices and in a reliable manner to test any four-wire connection established between two arbitrary switching points via at least one relay point by means of corresponding relay operations with respect to through-links ordered by control devices, as well as for impeccable transmission of digital signals.

According to the present invention, this is achieved

in that a first four-wire connection via an intermediary point is built up between a test device that can be reached by all connection points, and the calling connection point, and a first digital test signal produced by this test device is sent via the transmission channel for one transmission direction in this four-wire connection , is looped in a switching point or relay point touched by this four-wire connection, to the transmission channel for the other transmission direction and

is routed back to the test device, that the first test signal passed back and forth over the first four-wire connection is compared in its place of origin with the first signal produced by the test device in order to derive from it information about correctly performed through-connection and defect-free transmission of digital signals, that in the at least after a successful test has taken place for the first four-wire connection that confirms a fault-free connection to the calling connection point, from the same test device or from another test device another four-wire connection is set up via an intermediary point that lies in the connection path determined by the end-to-end path increase from the calling to the called connection point, and which was already included in the first four-wire connection, and from this connection point is built up further on the determined connection path to the called connection point, that one of this test device generated other test signal is sent via the transmission channel line for the other transmission direction in the other four-wire connection between the test device and the called connection point, is led in a loop in a connection point or mediation point that is touched by this four-wire connection, to the transmission channel for the other transmission direction and is led back to the test device, and that the other test signal passed back and forth over the other four-wire connection is compared at its point of origin with the other signal produced by the test apparatus in order to derive from it information about correctly performed through-connection and defect-free transmission of digital signals.

The method according to the invention thus makes it in principle possible in a favorable way and with maximum flexibility to test any four-wire connection that is to be established between an arbitrarily calling and an arbitrarily called connection point, before the connection is put into operation as intended, and that without significant loss of time, and while building

ning of the connection is in progress. When the first four-wire connection through to the calling switching point in any connection setup is tried first, and the second four-wire connection,

leading to the called connection point, only in the case of well-

the successful test is connected and tested, and since each of these centrally arranged test devices is only briefly connected each time to the respective four-wire connection and the rest of the time is available for testing further four-wire connections,

allows these tests to be carried out with a relatively small number of test devices.

By means of another test in addition in accordance with requirement 2

is it still possible to further increase the safety of the test

to a significant extent, as it can be determined whether the test signal was really fed back to the test apparatus during the first test via

the correct loop switch.

With reference to the drawing, the above-mentioned method will be explained in more detail in the following. Fig. 1 and 2 illustrate the testing of the different stages in the set-up of a connection set-up. Fig. 3 shows a fully connected connection in the remote messaging network.

For the sake of clarity, only each of the two transmission directions in a four-wire connection is always drawn between the individual connection points S and transmission points V. Of course, several four-wire connections are to be understood hereunder, and in the case of a time-sharing telecommunications network at least one time-sharing line with a system-dependent number of time-sharing channels. Furthermore, the drawing shows three test devices and three selector units WE as well as two control devices ST. They can also be found in a smaller or larger number of test devices P and voter units WE, and the test devices P are either assigned to the individual voter units or distributed among the mediation locations V. It is important that each test device P as well as each voter unit WE have access to all connection points S and mediation points

V.

Likewise, there may be additional control devices ST

which is distributed among all transmission points V and connection points S

or are arranged centrally so that they can be reached from all connection points S and transmission points V.

In the case of a time-sharing telecommunications network, the test devices P, the selector units WE and the control devices ST are appropriately connected to the relaying points via time-sharing lines. Thereby, several four-wire connections that are built up via different time-division channels can be tested at the same time with a time-division test device

P.

In each transmission point V as well as in each connection point S

with any four-wire connection, a connection loop SL can be passed through from the transmission channel for one transmission direction to the transmission channel for the opposite transmission direction. * This loop SL can be provided in different ways in connection points S and relay points V, which must have different tasks. Thus the loop can

SL is formed and canceled on command from a control device ST. In other connection points S or mediation points V, a permanent loop SL exists between each transmission channel for one transmission direction and the currently assigned transmission channel for the opposite transmission direction as long as these transmission channels are not covered with a connection. In this case, the loop SL becomes on command from a control device ST, e.g. after the test has taken place, canceled during the duration of the signal transmission and established again after its termination.

In the case of a connection to a calling and/or called analogue switching point which processes analogue signals, the loop formation for the digital sample signal takes place in that of those in the transmission of digital signals in participating digital switching points which are closest to the relevant analogue switching point.

Fig. 1 shows the test of a first four-wire connection which, on command from a control device ST, is built up from a selector unit WE2 via the relaying points V4, VI V3 and the switching points S2, Sl to a calling switching point Sk for recording election information. Of course, such a four-wire connection to the calling connection point Sk could just as well have been built from another selector unit Vtol or WE3. This first four-wire connection from the selector unit WE2 to the calling switching point Sk is now tested with regard to correctly performed through-connections in the switching points S and the relaying points V as well as for the fault-free transmission of digital signals by a test device P2 which is assigned to one of the relevant selector units WE. A first digital test signal, produced by this test device P2, is sent out via the selector unit WE2 and the transmission channel used in one transmission direction for the first four-wire connection to be tested is looped in the connection point Sk to the one in the opposite transmission routing direction used transmission channel for the four-wire connection to be tested, and is routed via the selector unit WE2 back to the test apparatus P2. This first test signal, which is sent back and forth over this first four-wire connection, is compared in the test device P2 with the first test signal that was produced therein. Correspondence thus means a defect-free connection of this first four-wire connection from the connection point Sk via the connection points Sl, S2 and the mediation points V3, VI and V4 to the selector unit WE2, as well as a defect-free transmission of digital signals without signal falsification on this connection. In order to provide full security that this first four-wire connection is tested up to the connection point Sk, while the first test signal is being sent, another test is carried out, on command from a control device ST, by removing the connection loop SL in the connection point Sk. In the test apparatus P2, it is now checked

if the first test signal does not appear after the loop interruption has been carried out. This second test provides certainty that the first test signal during the first test really reached the connection point Sk and only there was the loop connected to the return line.

After testing and confirmation of the first fault-free four-wire connection between the switching point Sk and the selector unit WE2, the loop SL in the switching point Sk is canceled and the first four-wire connection for the transmission of the selection readiness sign from the selector unit WE2 to the switching point Sk as well as of the selection information from the switching point Sk to selector unit WE2 released. Due to d n relayed selection information from the calling switching point Sk to the selector unit WE2 then follows, on command from a control device ST, in a known manner

at end-to-end path increase the construction of another four-wire connection, namely to the called connection point Sn. Of course, the construction of this second four-wire connection takes place from a relay point that was already part of the first four-wire connection that leads to the calling connection point Sk.

Fig. 2 shows the connection of the test device P2 via the selector unit WE2 and the relaying point V4 to the second four-wire connection, which leads to the called switching point Sn via the relaying points VI, V5, a connection that takes place in the switching point VI, which already entered

in the first four-wire connection to the calling connection point Sk. The testing of this second four-wire connection therefore takes place with the same test device P2 with which the first four-wire connection was also tested via the same selector unit WE2 and via the same relaying points V4 and VI. Of course, however, this second four-wire connection could also have been tested from another test device, or from another time channel in the same time division test device. Another digital test signal produced by this test device P2 is sent via the selector unit WE2 and the transmission channel used in one transmission direction for the other four-wire connection to be tested,

is led in the connection point Sn in a loop to the transmission channel used in the opposite transmission direction for the four-wire connection to be tested, and is routed back to the test device P2 via the selector unit WE2.

This second test signal, which is sent back and forth over this other four-wire connection, is compared in the test device P2 to the second test signal that was produced in it. Correspondence thus means a defect-free connection of this other four-wire connection from the connection point Sn via the connection point S5 and the mediation points V5, VI and V4 to the selector unit WE2 as well as a defect-free transmission of digital signals without signal falsification on this connection. In order to provide full certainty that this other four-wire connection was tested up to the connection point Sn, another test is carried out on command from a control device ST by canceling the connection loop SL in the connection point Sn, while the transmission of the second test signal is still in progress . In the test device P2, it is now checked whether the second test signal is not present after the loop interruption.

This second test provides certainty that the second test signal during the first test really reached the connection point Sn and only there was the loop connected to the return line. After the end of testing and confirmation of the second fault-free four-wire connection between the connection point Sn and the selector unit WE2, a through-connection from the first four-wire connection to the second four-wire connection takes place in the mediation point VI, while separating the connection section that leads via the selector unit WE2 to the test device P2 . Fig. 3 shows the fully connected four-wire connection from the connection point Sk to the connection point Sn.

If, on the other hand, during a first test no test signal occurs in the test device P that has been sent back and forth over a four-wire connection, or such a test signal is incomplete or falsified in relation to the test signal that was produced in the test device P, then this indicates a defective or incorrectly executed through connection in one or more of the connection points S and/or mediation points V that participate in the construction of this four-wire connection. In order to limit such a defective or incorrect through-connection, the loop SL between the two transmission channels in a connection point S and/or mediation point V can be moved from this to another connection point S and/or mediation point V on command from a control device ST, until there in the point of origin of the test signal, i.e. in the test device P, a flawless test signal occurs.

Claims (14)

1. Procedure for testing four-wire connections between two connection points that are to be connected to each other in a centrally controlled telecommunications network with end-to-end path extension, with regard to through-connections ordered by control devices, and defect-free transmission of digital signals, characterized in that a first four-wire connection via a relay point (V) is built up between a test device (P) that can be reached by all switching points (S), and the calling switching point (S), and a first digital test signal produced by this test device (P) is sent via the transmission channel for one transmission direction in this four-wire connection is led in a loop in a connection point (S) or mediation point (V) which is touched by this four-wire connection, to the transmission channel for the other transmission direction and is led back to the test apparatus (P ), that the first test signal passed back and forth over the first four-wire connection is compared in its place of origin with that of the test apparatus t produced the first signal in order to derive from it information about correctly performed switching and defect-free transmission of digital signals, that at least after a successful test has taken place for the first four-wire connection that confirms a defect-free connection to the calling connection point (S), from the same test device (P) or from another test device (P), another four-wire connection is built up via a relay point (V) located in the connection path determined by the end-to-end path increase from the calling party to the called connection point (S), and which was already included in the first four-wire connection, and from this connection point (V) is built up further on the determined connection path to the called connection point, that another test signal produced by this test device (P) is sent via.. the transmission channel for the other transmission direction in the other four-wire connection between the test device (P) and the called connection point (S) is looped in a bling site (S) or transmission site (V) which is touched by this four-wire connection, to the transmission channel for the other transmission direction and is routed back to the test device (P), and that the other test signal forwarded and returned over the other four-wire connection is compared in its place of origin with the other signal produced by the test apparatus in order to derive from it information about properly executed through-connection and defect-free transmission of digital signals. 2. Procedure as stated in claim l, characterized by the fact that if the test is successfully carried out, another test is always carried out during the transmission of the test signal by canceling the loop in the connection point (S) or the transmission point (V). 3. Method as stated in claim 1, characterized in that the test signal is fed in a loop in the calling connection point (S) in a first four-wire connection and in the called connection point (S) in another four-wire connection. 4. Procedure as specified in claim 1 in the case of analog switching points occurring in the same network that process analog signals, and digital switching points that process digital signals, characterized in that the test signal in a connection to a calling and/or called analog switching point (S) is looped to the digital switching points (S) included in the transmission of digital signals that are located nearest analogue connection point (S) in question. 5. Method as stated in claim 3 or 4, characterized in that the loop (SL) between the two transmission channels in a connection point (S) and/or mediation point (V), when a non-flawless connection is detected, on command from a control device ( ST) is moved from one connection point (S) and/or transmission point (V) to another connection point (S) and/or transmission point (V) until a defect-free test signal is received at the point of origin, in order to limit the section of the four-wire connection that is be-ridden with errors. 6. Procedure as specified in one of claims 1-4, characterized in that the test is carried out for each connection structure. 7. Method as stated in claim 1 or 2, characterized in that in the connection points (S) and/or the mediation points (V) at all times with uncoated transmission channels, a loop is led from the respective transmission channel for one transmission direction to the corresponding transmission channel for the other transmission direction, and this loop is canceled on command from a control device (ST). 8. Method as specified in claim 1, characterized in that the loop formation is carried out and canceled on command from a control device (ST). 9. Method as stated in claim 1, characterized in that the test operation is interrupted in the event of a faulty connection to the calling connection point (S). 10. Method as stated in claim 1, where each test device is assigned a selector unit, characterized in that the connection established from the calling connection point (S) to the selector unit (WE) is used as the first four-wire connection, and the testing of it to the called connection point (S) leading four-wire connection is carried out before the selection. 11. Method as stated in claim 1, characterized in that the same test signal is used as first and second test signal. 12. Method as stated in claim 1, characterized in that after successful testing of both the four-wire connection leading to the calling and the called connection point in the common relay point (V) for the first and second four-wire connection is made a through connection between the four-wire connection section leading to the calling connection point (S) and the four-wire section leading to the called connection point (S) while separating it, resp. the connection sections leading to the test apparatus (P), resp. -the devices (P). 13. Method as stated in claim 1, in a time-sharing telecommunications network, characterized in that the first digital test signal produced by a channel of the multiplex test device (P) is only transmitted in the time-sharing channel used for the first four-wire connection in one transmission direction , is looped in a connection point (S) or relay point (V) which is touched by this four-wire connection, to the time division channel used in the other transmission direction, and is led back to the multiplex test device (P) on this time division channel, and that the other test signal produced by the same time division channel of the multiplex test device (P) or by an arbitrary channel of the same or another multiplex test device is only transmitted in the time division channel used for the other four-wire connection in one transmission direction , is placed in a loop in a switching point (S) or mediation point (V) which is touched by this four-wire connection, to the time division channel which is used in the other transmission direction, and is fed back to the multiplex sampler (P) on this time division channel. 14. Method as stated in claim 13, characterized in that several four-wire connections built up via different time division channels with the same multiplex test apparatus (P) are tested simultaneously.