CH670021A5 - - Google Patents

Description

DESCRIPTION The present invention relates to a test method according to the preamble of claim 1.

A telecommunications switching system constructed according to this concept is known from CH-PS 651 163 and is also described in detail in “Siemens-Albis reports” 36 (1984) 2/3, pages 31 to 48. In the patent mentioned, among other things, explained that in the 2 Mbit / s time multiple lines of the connection circuit groups for digital connecting lines between the group coupler and the multiplexer or the interface to the switching network, an echo can be inserted if necessary. This is the case when long lines, e.g. international long-distance lines to be connected to appropriate connection circuit groups and signals from a subscriber that are partially reflected at the far end of the transmission link at the 4-wire / 2-wire transition must be prevented from returning as an echo to the speaking subscriber.

Such an echo blocker for a four-wire transmission system is known for example from DE-AS 24 35 607. This contains a blocking element inserted into the transmission path and an attenuator inserted into the reception path. If only a certain level occurs in the reception path, the normally permeable blocking element is activated. The attenuator, on the other hand, is activated when a certain level occurs simultaneously in the receive and transmit paths. The object of the present invention is now to provide a method in order to be able to test the correct functioning of such digitally operating echo blocks within a switching system as simply and reliably as possible. This is achieved according to the invention with a method as characterized in claim 1. Further developments are specified in further claims.

The proposed method enables a testing of different characteristic operating states of echo locks and requires practically no circuit extensions in the switching system for this. Above all, it can be implemented by means of additional processes in control devices that are already present, without disrupting the normal switching traffic, which of course has first priority.

The invention is explained in more detail below with reference to drawings, for example. It shows:

1 shows the structure of a switching system in which the invention can be used,

2 shows the block diagram of a line circuit group of this switching system,

3 details for testing the echo blocks in a line circuit group,

Fig. 4 is an explanatory diagram.

1 shows a rough block diagram of a telecommunication switching system which is described in detail in the references mentioned at the beginning and is operated according to the time-division multiplex method. Details of the system are therefore only described here to the extent necessary to understand the present invention. The periphery of the system is divided into several different LTG connection circuit groups, of which the four groups LTGA ... LTGB are shown. These form the interfaces between the connected various incoming and outgoing lines and the switching organs. These can be analog or digital subscriber lines ATL or DTL or analog or digital connection lines AVL or DVL (such as PCM multiple lines). The LTG connection circuit groups are designed for the reception of signaling characters using different signaling methods. Each of the connection circuit groups LTG has its own decentralized control unit GP, the message exchange between these and the central control unit CP of the switching system being carried out via a central switching network SN, via which the actual voice connection paths are also set up.

2 shows details of a line circuit group LTGD of this switching system. Analog and digital lines can be connected to this connection circuit group. 30 analog lines are connected to a multiple connection circuit DIU via a PCM multiplexer MUX with A / D converter. Digital lines from PCM 30/32 systems, on which the signals are already transmitted in the form of PCM words, are connected directly to assigned multiple connection circuits DIU. The four multiple connection circuits DIU of the connection circuit group LTGD are multiplex lines which lead via a group coupler SPMX designed as a time coupling stage

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connectable to the switch-through network SN, which can be reached via an interface LIU. In addition to the actual voice channels, the data channels used to exchange messages with the central control unit CP also lead via these multiplex lines. All switching-related tasks are handled by the decentralized control unit GP of the connection circuit group LTGD in cooperation with the central control unit CP. These tasks essentially consist of receiving the incoming line and register characters and evaluating them over time, and of forwarding the received characters to the central control unit CP in a suitable form. Furthermore, at the command of the decentralized control unit GP, line and register characters are transmitted and audible tones are emitted via a character transmitter TOG, which is also connected to the group coupler SPMX. The character transmitter TOG generates characters with different frequencies, whereby the characters are delivered in digital form. The central control unit CP essentially carries out the digit analysis and routing, it also takes over the route search in the interconnection network SN and controls the establishment of connections via the interconnection network SN.

The decentralized control unit GP relieves the central control unit CP by processing incoming switching information, such as line and register characters, and feeding the central control unit CP only the information in the form of messages that it needs in the context of its tasks. The decentralized control unit GP also monitors the state of the lines connected to the connection circuit group LTGD, and also takes over the control of the group coupler SPMX, which is constructed as a one-stage, non-blocking time stage. The group coupler SPMX is connected to the switching network SN via the interface LIU, in which multiplexing from 4x2 to 8 Mbit / s takes place. The LIU interface not only enables the individual switching of the voice channels in both directions (from and to the switching network SN), but also a direct connection between the reception path and the transmission path of any channel. In the 2,048 Mbit / s time multiple connection lines between the group coupler SPMX and the interface LIU, a digital echo blocker ES is inserted, which has a transmission path block in the transmission path and an attenuator in the reception path. The attenuator is activated when a certain signal level is exceeded in both the receive and transmit path. The transmission path block, on the other hand, is activated if a certain level is only reached in the reception path. In the case of short echo delays or data transmission, the echo blocker ES is deactivated from the decentralized control unit GP or by a signal of a certain frequency (tone disabling), usually 2100 Hz, i.e. Transmission path lock and attenuator deactivated. An echo suppressor ES is assigned to each multiple connection circuit DIU. An echo blocker ES thus serves 30 voice channels. It can be switched on and off channel by channel from the decentralized control unit GP.

As shown in Fig. 3, the decentralized control unit GP contains, among other things. a processor PU with a character buffer SIB and a character multiplexer SMX, which distributes the signaling data of the lines or decentralized devices (echo locks, multiple connection circuits) of the connection circuit group LTGD in the output direction and collects them for processing in the input direction. In addition to the control of the echo lock ES mentioned above, the character multiplexer SMX also controls the group coupler SPMX and the interface LIU. 3 shows the configuration for testing an echo suppressor ES. For this purpose, for a channel X under consideration, the transmission path XS containing the transmission path block SP symbolically represented by a changeover switch and the reception path XE containing the bridgeable attenuator DG are shown. If the transmission path is blocked, the switch is in the BM position. The receive path XE and the send path XS can be interconnected at the instigation of the decentralized control unit GP via the interface LIU. The channel-wise interconnection of receive and transmit path in the interface LIU is either possible either directly or via an inverter INV and a downstream switch PS. Via the group coupler SPMX, the reception path XE can also be connected to an output TBA and the transmission path XS can be connected to an input TBI of the character multiplexer SMX. It is also possible to connect the receive path XE to the character transmitter TOG via the group coupler SPMX instead of the output TBA. All the views necessary for the test of the echo blocker ES described below are carried out by the decentralized control unit GP, which issues the appropriate switching commands to the group coupler SPMX and the interface LIU. This configuration enables the connection of the same or different signals to the transmit XS and to the receive path XE of the echo suppressor ES for each channel.

According to CCITT (study Group XV, Temporary Document No. 52-E, Appendix II), the following conditions apply to the different operating states of a digital echo canceller ES:

The neutral state, i.e. The transmission path block and the attenuator are inactive and are used when the signal level is <-31 dBmO in both the reception and transmission paths. The locked state, i.e. the transmission path block is active, is adopted if the signal level on the reception path is> -31 dBmO and at the same time greater than the signal level on the transmission path. This corresponds to the state when the remote subscriber is speaking. This prevents the signals arriving from the remote node from returning to it as an echo. The attenuation state with the active attenuator of 6 dB occurs when the transmit level is> -31 dBmO in both the receive and the transmit path. This is the case when both (the near and far) participants speak (double-talk state).

4, these operating conditions are clearly shown in a diagram, the level of the reception path XE being plotted on the abscissa and the level of the transmission path XS in dBmO being plotted on the ordinate. In area I the echo blocker is in the neutral state, in area II it is in the blocked state and in area III it is in the double-talk state. The characteristic curve b is shifted downwards by 6 dB compared to the characteristic curve a. The characteristic curves a and b enclose an area IV which corresponds to a hysteresis area which ensures that the double-talk state is maintained if the signal level in the transmission path XS only drops slightly below the level which causes the damping to be switched on. If the echo blocker moves from a state in region III to a state in region II, the switchover (attenuator off, transmission path block on) takes place only on characteristic curve b. In the opposite case, the transition from area II to area III, the switchover (transmission path lock off, attenuator on) takes place on the characteristic curve a. The working lines c and d correspond to states that can be set with the test configuration according to FIG. 3, in which the signal level on the sending path XS is inverted compared to that on the receiving path XE, the working line c being the undamped case and the working line d being the damped case.

As already mentioned briefly, the echo blocker ES can be deactivated from the decentralized control unit GP or by a frequency of 2100 Hz. Their normal function is suppressed by bridging the attenuator DG and keeping the transmission path block SP switched on. It contains a logic link SGI (FIG. 3) that controls the bridging of the attenuator DG and a logic link SG2 that controls the transmission path block SP. An on5

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gang of the two logic elements SGI and SG2 is connected to outputs of a level evaluation circuit PB, which determines the signal levels on the receive and transmit paths and controls the echo blocker ES accordingly. The other two inputs of the logic elements SGI and SG2 are connected to the character receiver ZE and the decentralized control unit GP. The character receiver ZE is connected on the input side to the reception path XE and the transmission path XS.

In certain signaling methods between exchanges in a telecommunications network, the transmitted identifiers do not contain any information as to whether data or voice signals are to be transmitted via a connection to be set up. In the case of satellite connections or other long connections, the switching center therefore automatically activates the echo blocker ES, specifically via the decentralized control unit GP of the relevant connection circuit group LTGD, by applying a corresponding signal to the logic elements SGI and SG2 on the basis of a corresponding command from the central control unit CP. If data is to be actually transmitted via such a connection, the echo blocker ES must be deactivated again. This is done by feeding a frequency of 2100 Hz into the connection from the data transmitter for a certain time. As soon as no more data is transmitted, the echo blocker ES becomes effective again due to the resting level that occurs. This function is simulated in the present test procedure by connecting the TOG character transmitter via the group coupler SPMX to the relevant channel. The character transmitter TOG remains switched on for a certain time and emits a frequency of 2100 Hz which is received in the character receiver ZE and causes the latter to switch the echo blocker ES ineffective via the logic elements SGI, SG2, i.e. to bridge the attenuator DG and to make the transmission path block SP ineffective.

As part of the test to be carried out for this purpose, the following properties of the echo blockers ES should be checked:

1.Transparency in the neutral state (test point 1 in Fig.

4),

2. Attenuation measure of 6 dB with the attenuator switched on (test point 2) in the double-talk state,

3. Deactivating the echo blocker from the double-talk state either by the decentralized control unit GP or a frequency of 2100 Hz (tone disabling) and checking the transparency in this state (test point 3),

4. blocking state of the echo block (test point 4),

5. Deactivation of the echo blocker from the blocking state either by the decentralized control unit GP or by a frequency of 2100 Hz (test point 5),

6. Dynamic behavior of the echo suppressor ES, e.g. Time behavior for the transition from the double-talk state to the blocked state and vice versa.

For the test, as soon as the test configuration shown in FIG. 3 has been created for the channel to be tested at the instigation of the decentralized control unit GP, the reception path XE via the output TBA of the decentralized control unit GP is acted upon in succession with various test bit patterns, which after passing through the group coupler SPMX , the echo blocker ES and the interface LIU (either directly or via the inverter INV), depending on the operating state of the echo blocker ES, result in an unchanged or changed bit pattern at the input TBI of the decentralized control unit GP. The received bit pattern is analyzed in the processor PU and the result is used to determine whether the echo blocker ES is working properly. By connecting the inverter INV in the interface LIU it is achieved that the reception and transmission path can also be acted on simultaneously with different test bit patterns. The test bit patterns which arrive in each case on the receive path and the transmit path are selected such that the echo blocker ES reaches a certain desired operating state. For example, the echo blocker ES with the test arrangement according to FIG. 3 can be brought into the operating states corresponding to the test points 1 to 5 shown in FIG. 4 in any order. The test bit patterns used in this example correspond to the following signal levels in the receive XE or transmit path XS and have the following appearance (TP = number of the test point in FIG. 4):

Level at the input XEE ^ EA Level at the input XSE of the reception path XE of the transmission path XS

TP

dBmO

Test bit pattern dBmO

dBmO

Test bit pattern

1

-40

X1011011

-40

-40

X1011011

2nd

-22

X1101001

-22-6

-13.5

X0000110

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-22

XI101001

-22

-19.5

X0010110

4th

-2

X0100100

-2

-40

X1011011

5

0

X0100011

0

-44

X1011100

The XEA column in the table contains the levels that occur at the output of the receive path XE (point XEA). The bit with the highest significance corresponds to the sign and is irrelevant in the present context and is therefore designated with X in the table.

In contrast to test point 1, for test points 2 to 5, the bit patterns applied to the transmission path XS before the transmission path block SP are inverted bit by bit compared to the bit patterns occurring at point XEA, the inversion being carried out by connecting the inverter INV in the interface LIU.

The test bit patterns are formed by coding the desired signal level using the 13 segment coding characteristic curve standardized by CCITT and then converting it into the NINI (non-inverted, inverted) code used after the A / D conversion. For example, from the level -2 dBmO according to the coding pattern assigned to the Buti pattern XI110001 by inversion of every 2nd bit (from the left), the bit pattern X0100100 in the NINI code is used, which is used as a test bit pattern to be applied to the reception path XE for checking the operating state according to test point 4.

Test point 1, which characterizes the neutral state of echo blocker ES, is obtained by applying test bit pattern X1011011 to receive path XE and unchanged, i.e. non-inverted looping set in the LIU interface to the XS transmission path. In this case, the decentralized control unit GP must check whether the bit pattern received via its TBI input is identical to the bit pattern transmitted via the TBA output.

Test point 2 corresponds to the operating state of double talking. The bit pattern XI101001 is applied to the receive path XE, so that the inverted bit pattern X0010110 first reaches the send path XS at the output of the inverter INV (point XSE). Since with this constellation of level values the attenuator DG normally takes effect, attenuation by 6 dB must take place in the receive path, which then corresponds to a test bit pattern XI111001 at the input of the inverter INV (point XEA). As a result, a test bit pattern X0000110 finally arrives on the transmission path XS and from there to the decentralized control unit GP for checking.

Test point 3 is set starting from test point 2, in that the echo blocker ES is deactivated either from the decentralized control unit GP or by switching on the character transmitter TOG with a signal of 2100 Hz. There

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the attenuator DG is no longer effective in this case, the bit pattern XI101001 applied to the receive path XE must reach the inverter INV unchanged and from there inverted to the send path XS, which in turn can be checked in the decentralized control unit GP.

Test point 4, which corresponds to the blocking state, is set by creating test bit pattern X0100100 on receive path XE, which must result in a bit pattern X1011011 corresponding to a level of -40 dBmO by inversion in interface LIU at input XSE of transmission path XS. In this operating state, the transmission path block SP assumes the position BM and consequently a hard-wired bit pattern characterizing the block state arrives at the input TBI of the decentralized control unit GP, where the appearance of this bit pattern is checked.

In test point 5 it is checked whether the blocking status can be released either from the decentralized control unit GP or by switching on a frequency of 2100 Hz. If the blocking state is released, a test bit pattern X0100011 applied to the reception path XE reaches the input TBI of the decentralized control unit GP in inverted form via the inverter INV, where the check takes place. To check that the echo blocker ES is deactivated, it is sufficient, for example, to switch off the echo blocker ES in the blocked state from the decentralized control unit GP and in the double-talk state by switching on the character transmitter TOG.

The decentralized control unit GP also checks the timing behavior of the echo blocker when changing from one operating state to the other or when the decentralized control unit GP or the signal transmitter TOG is inactive. 5 An error is detected if the echo lock ES reacts incorrectly, i.e. if a test bit pattern expected via the transmission path XS does not arrive in the decentralized control unit GP within a certain time.

The test described is carried out periodically for each io voice channel. The test procedures required for this are stored as a program in the decentralized control unit GP. The test is initiated automatically from the decentralized control unit GP. Only voice channels that are not currently occupied can be included in the test, i.e. the establishment of speech connections always has priority in the exchange. An operator can also initiate the test via an MML interface.

The principle of feeding test bit patterns into the receive 20 XE or transmit path XS on which the proposed test method is based offers the advantage over a method with feeding different signal frequencies that the evaluation to be carried out in the decentralized control unit GP is relatively simple. For example, to check the damping dimension of the echo suppressor ES, no complex performance analysis is required, which has an advantageous effect on the dynamics of the decentralized control unit GP.

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4 sheets of drawings

Claims (4)

670 021 1.Procedure for testing digital echo blocks in a telecommunications switching system operated according to the PCM time division multiplex method with groups (LTGD) of connection circuits (DIU) to which PCM connecting lines are connected, which groups (LTGD) each have a decentralized control unit (GP) and which can be connected to set up connection paths via a dedicated group coupler (SPMX) and at least one time multiple line with a downstream interface (LIU) with the participation of a central control unit (CP) with a central interconnection network (SN), with one connection circuit (DIU) between the group coupler (SPMX) and the interface (LIU) an echo blocker (ES) is inserted, which has a blocking element (SP) inserted into the transmission path (XS) and an attenuator (DG) inserted into the reception path (XE), whereby when only signal level on the receiving path, the blocking element (SP) and when there is a simultaneous occurrence of receiving path and transmission On the signal side, the attenuator (DG) is activated, characterized in that, in order to test certain operating states of an echo lock (ES), the level values corresponding to such an operating state in the receive (XE) and in the transmit path (XS) are each set by the decentralized control unit (GP) from the group coupler (SPMX) channel-specific test bit pattern to the receive path (XE) of the echo blocker (ES) and via the interface (LIU) either unchanged or inverted the send path (XS) of the corresponding channel of the echo blocker ( ES) is supplied, and that the bit pattern that consequently appears on the transmission path (XS) is in turn sent back to the decentralized control unit (GP) via the group coupler (SPMX) and there checks the correct behavior of the echo blocker (ES) by comparison with a reference bit pattern becomes. 2. The method according to claim 1, characterized in that the ineffective switching of the echo blocker (ES) is checked in that in the operating state "double talk" and in the operating state "blocked" either a corresponding setting signal from the decentralized control unit (GP) or an external one Signal with a certain frequency is applied to the echo blocker (ES). 2nd PATENT CLAIMS 3. The method according to claim 2, characterized in that the external signal is applied by connecting a character transmitter (TOG) via the group coupler (SPMX) to the reception path (XE) of the relevant channel of the echo blocker (ES). 4. The method according to any one of the preceding claims, characterized in that the bit patterns arriving in the decentralized control unit (GP) are also checked with regard to their correct arrival in time.