EP1123632A1 - Method for data qualification and for assisting in fault localization on a digital telecommunication network - Google Patents

Abstract

The invention concerns a system and a method for qualifying data and assisting in fault localization in a digital telecommunication network. The invention is characterised in that it consists in: detecting anomaly and/or fault data; discriminating between the anomalies and/or faults coming from the client-site or operator-site; generating at least a signal representing the type and origin of said fault; then analysing the generated signal to deduce therefrom the origin and type of the anomaly and/or fault.

Description

 METHOD FOR QUALIFYING INFORMATION AND HELPING TO LOCATE DEFECTS ON A DIGITAL NETWORK

The present invention relates to a system and a method for qualifying information and helping to locate faults in a digital telecommunications network comprising a plurality of transmission equipment arranged between at least a first client site and at least a second client site exchanging, via at least one operator site, digital data in raster or non-raster mode, each client site being connected to the network via network-client interface equipment capable of discriminating anomalies and / or faults from the customer site or the operator site. The invention relates particularly but not exclusively to a method intended to be implemented in a digital network, such as for example the leased lines El / Tl, E2 / T2, E3 / T3, E4 (1.5 Mbit / s at 140 Mbit / s) to provide telecommunications operators with reliable information on the location of any faults.

The liberalization of telecommunications at national and international level has generated strong competition between operators which has led them to draw up contracts in which they undertake to provide users of national and international digital networks with a guarantee of their quality and recovery time for any faults.

The criteria used for the calculation of quality (QoS) and the location of faults generally used are based on standards international (ITU-T, ETSI). Based on these standards, operators commit to their customers on two main parameters: the maximum annual (or monthly) period of unavailability of the services sold, also called "Guaranteed Maximum Downtime in English" GMD.

- the Relay Time Guarantee, GTR also called "Guaranteed Time to Repair in English", which represents the maximum time the operator has to repair a defect before paying penalties. The GTR is most often expressed in hours. The quality criteria (QoS) generally used are based on international standards (ITU-T G.826, NMF 701) which define availability, and the "Service Level Agreement" (SLA in English) According to these standards, availability is defined by a typical value parameter 99.9%, which results in nine hours of unavailability of the service per year, the backup time guarantee (GTR) has a typical value of two. hours or four hours and corresponds to the minimum time allowed to the operator to restore the service as soon as a problem is notified to him by the customer. The SLA is a weighted combination of parameters G.826 and GTR. Current standards do not provide not the qualification of the relevant information to calculate the quality of service (QoS) and the SLA. Therefore, any false detection of this information results in an artificial deterioration of the Qos and the SLA. This deterioration can oblige the operators of telecommunications to move response personnel and to pay penalties wrongly.

In addition, these standards do not provide for the possibility of locating faults on all sections of conduits in digital networks.

The object of the invention is to solve the above problem by means of a method making it possible on the one hand to guarantee the operator the information and the quality parameters, and on the other hand, to locate in real time possible faults on digital telecommunications networks such as leased lines.

The method according to the invention is characterized in that anomaly and / or defect information is detected in the portions of the network located between the client sites, anomalies and / or faults originating from the site are discriminated against. client or site operator, at least one signal representative of the type and origin of the anomaly and / or of the detected fault is generated, and the signal generated is analyzed to deduce the origin and nature of this anomaly and / or this fault. The method according to the invention thus allows the operator to carry out:

- proactive supervision of their end-to-end services (from customer site to customer site);

- the provision of instant and reliable means of locating faults without moving staff and without intervention at the customer.

Preferably, the method according to the invention further comprises the following steps: a- an acquisition step consisting in collecting, dating and synchronizing anomaly and fault information at at least one point on the network, then in sorting and isolating incoming information, outgoing information and end-to-end information , then to record this information in a buffer memory, b- a test step consisting in checking whether an incoming information generates an end-to-end information and / or an outgoing information; c- a correlation step consisting in repositioning in time the incoming information in one direction and their consequent action on the end-to-end information circulating in the opposite direction then in calculating at least one parameter representative of the quality and / or performance of the network or part of it; d- a step of validating the relevance of the information at each of the previous steps; e- a step for processing the information validated in the previous step;

Thanks to this process, operators can optimize the quality of the service they provide to their customers. According to an important characteristic of the invention, when the digital data are transmitted in non-screened mode, the signal generated is either a first signal SI of the SIA type (Alarm indication signal) scrambled, or a second signal S2 of the type IAD (Remote Alarm Indication Signal) scrambled, i.e. a third S3 signal of the IAD scrambled type. AT By way of nonlimiting example, the first signal SI is obtained by scrambling a first sequence Ml coded on a first number nor of bits, the signal S2 is obtained by scrambling a second sequence M2 coded on a second number n2 of bits, the signal S3 is obtained by scrambling a third sequence M3 coded on a third number n3 of bits.

When the digital data is transmitted in raster mode, the signal generated is either a fourth signal S4 of type SIA partially modified, or a fifth signal S5 of type IAD carrying a first code, or a sixth signal S6 of type IAD carrying a second code .

Other characteristics and advantages of the invention will emerge from the description which follows, taken by way of nonlimiting example, made with reference to the model of a leased line (LL) in a multi-operator or client-operator application. with services using the non-screened mode or the screened mode on digital telecommunications networks and with reference to the appended figures in which:

FIG. 1 schematically represents a leased link in a digital multi-operator communication network in which a system according to the invention is installed; FIG. 2 represents a block diagram illustrating a method according to the invention; FIG. 3 represents a block diagram illustrating an acquisition step according to the invention; - Figure 4 shows a block diagram illustrating a test step according to the invention; - Figure 5 shows an example of implementation of the method in a network over which digital data pass in non-screened mode; FIG. 6 represents a flowchart illustrating an example of data processing at the site-operator level according to a method according to the invention in a network over which digital data pass in non-screened mode;

- Figure 7 shows an example of implementation of the method in a network over which digital data pass in raster mode; FIGS. 8 and 9 represent a flow diagram illustrating an example of data processing according to a method according to the invention in a network over which digital data pass in raster mode.

FIG. 1 illustrates a system for qualifying information and helping to locate faults in a digital telecommunications network comprising a plurality of transmission equipment arranged between at least a first customer site and at least a second customer site exchanging, via at least one operator site, digital data in raster or non-raster mode, each client site being connected to the network via network-client interface equipment.

According to a first important characteristic of this system, each network-client interface equipment comprises means capable of discriminating anomalies and / or faults originating from the client-site or from the operator-site, means for generating at least one signal representative of the type and origin of the defect, means for analyzing the signal generated so as to deduce therefrom the origin and the nature of the anomaly and / or of the defect.

As illustrated in FIG. 1, two remote devices A and B integrating said network-client interface equipment are connected in a digital network 20, through a leased link LL. In order to detect the anomalies likely to affect the communications in the networks 20, one or a plurality of probes (not shown) are placed between the remote devices A and B in order to collect and analyze the relevant information to calculate at least one network quality and / or performance criteria 20. A central device 21 is installed at 0 in one of the operator's premises. The remote devices A, B and the central device 0 are inserted in the cut-off on the leased link and exchange, via the operator site, digital data in raster or non-raster mode. The remote devices A and B ensure the acquisition and processing of the fault and / or fault information, while the central device 21 ensures the acquisition of the fault and / or fault information, the processing of this information and possibly the steps of testing and validating relevance. The line between customer sites A and B and central site 0 is divided into portions numbered from 1 to 16. Anomaly and / or fault information is detected in A, B, and 0 (and possibly in others intermediate points). In the event of an anomaly and / or fault detected in A and / or B, at least one signal representative of the type and origin of said fault is generated. In O, we analyze the different signal (s) generated to deduce the origin and the nature of the anomaly and / or defect. In a preferred embodiment of the invention, when the digital data are transmitted in non-screened mode, the signal generated is either a first scrambled signal SI of the SIA type (Alarm indication signal), or a second signal S2 of IAD (Distant Alarm Indication Signal) type scrambled, i.e. a third signal S3 of type IAD scrambled.

In addition, the first signal S1 is obtained by scrambling a first sequence M1 coded on a first number ni of bits, the second signal S2 is obtained by scrambling a second sequence M2 coded on a second number n2 of bits, and the signal S3 is obtained by scrambling a third sequence M3 coded on a third number n3 of bits.

In framed mode, the signal generated is either a fourth signal S4 of type SIA partially modified, or a fifth signal S5 of type IAD carrying a first code, or a sixth signal S6 of type IAD carrying a second code. As an example of implementation, the signal S4 is obtained by forcing part of the bits of an SIA signal at a logic level 1 for at least a determined time interval, the signal S5 is obtained by a first coding of a particular bit of an IAD signal, the signal S6 is obtained by a second coding of a particular bit of an IAD signal. The signal S4 is, for example, an all-to-one signal over the last thirty-one time intervals IT1 to IT32 of the 2 Mbit / s frame which includes thirty-two, the signal S5 can be obtained by a first coding of a national reserve bit associated with bit 4 of the ITO time interval of the 2 Mbit / s frame, and the signal S6 can be obtained by a second coding, different from the first coding, of a national reserve bit associated with bit 4 of the ITO time slot of the 2 Mbit / s frame.

In operation in non-screened mode, as illustrated in FIG. 5, when a fault of the MQS type or of the SIA type is detected at the level of the client interface on the client site (A or B), a signal SI to the operator site, when an MQS type fault is detected at the network interface on the customer site (A or B), an S2 signal is transmitted to the operator site and a type signal is forced SIA on the client side, when an SIA type fault is detected at the network interface on the client site (A or B), an S3 signal is transmitted to the operator site and an SIA type signal is forced on the client side, when an SI type signal is detected at the Network interface level on the client site (A or B), an SIA type signal is forced on the client side.

In addition, as illustrated in FIG. 6, in non-screened mode, the anomaly and / or fault information collected on each side of the point O is detected (see FIG. 1). This point O is, for example, a centralized control point at the operator. So when an SI, S2 or S3 type fault is detected on one side of the point O, a signal of the SI type is transmitted from the other side (to the operator-client demarcation point A or B); and when an MQS, SIA type fault is detected is detected on one side of the point O, an SIA type signal is transmitted on the other side (to the operator-client demarcation point A or B). In raster mode, as illustrated in FIG. 7, when a fault of the MQS or SIA type, or of the Loss of Frame Locking (PVT) type is detected on the side of the client interface on the client site (A or B) an alarm signal S4 is generated on the site-operator side, when an IAD type fault is detected on the side of the customer interface on the customer site (A or B) and in the absence of this type of MQS or SIA or PVT fault on the side of the network interface on the client site, this Remote Anomaly Indication (IAD) signal is propagated on the side of the operator site, when a fault of SIA or PVT type is detected on the side of the network interface on the client site, an S5 type signal is generated on the operator site side while inhibiting the IAD type signal on the operator site side and forcing an SIA type signal from the client side, when an MQS type fault is detected on the network interface side on the client site, an S type signal is generated 6 on the operator site side while inhibiting the IAD type signal on the operator site side and forcing an SIA signal type on the client side and the client side S5 or S6 signals are inhibited when detected at the level of the client-site network interface. In addition, as illustrated by FIGS. 8 and 9, in raster mode, the anomaly and / or fault information collected from each side of point O (see Figure 1). This point O is for example, a centralized control point at the operator. Thus, when an S4 type fault is detected on one side of point O, on the other side (an operator-client demarcation point (A or B), a SIA type signal is transmitted, and when an MQS, SIA or PVT type fault is detected on one of the sides of point O, a SIA type signal is transmitted on the other side (to the operator-client demarcation point A or B).

In non-screened mode, the fault location step illustrated in FIG. 6, consists in:

- inhibit signals of type S2 or S3 on the side of one of the client sites when a fault of another type is detected on the side of the other client site; locate the fault in portion 1 (respectively in portion 9) of the line, i.e. the first (respectively second) customer site when an SI type fault is detected at O on side A (respectively B);

- locate the fault in section 2 or 3 (respectively in section 10 or 11) of the line, i.e. upstream of the last transmission equipment before the central site when an SIA type fault is detected at O on side A (respectively B); locate the fault in section 4 (respectively in section 12) of the line, i.e. downstream of the last transmission equipment before the central site when a fault of MQS type or HDB3 error is detected in O from side A (respectively B);

- locate the fault in section 5 or 6 (respectively in section 13 or 14) of the line, i.e. upstream of the last transmission equipment after the central site when a S2 type fault is detected at O on side B (respectively A); locate the fault in section 7

(respectively in portion 15) of the line, that is to say downstream of the last transmission equipment after the central site when a fault of type S3 is detected at O on side B (respectively A).

Furthermore, in screened mode, as illustrated in FIG. 8 (respectively in FIG. 9), the fault location on the side of the first (respectively second) customer site consists in:

- inhibit signals of the IAD, S5 or S6 type on one side of the client sites when a fault of another type is detected on the side of the other client site; - locate the fault in section 1

(respectively in portion 9) of the line, that is to say upstream of the first customer site (respectively of the second), when a fault of type S4 is detected at O on side A (respectively B); - locate the fault in section 2 or 3

(respectively in portion 10 or 11) of the line, that is to say upstream of the last transmission equipment before the central site when an SIA type fault is detected at O on side A (respectively B); - locate the fault in section 4

(respectively -in portion 12) of the line, that is- ie downstream of the last transmission equipment before the central site when an MQS type fault or HDB3 error is detected at O on side A (respectively B); - locate the fault in section 2, 3, 4

(respectively in the portion 10, 11, or 12) of the line, that is to say between the first client site (respectively the second client site) and the central site when a PVT type fault or possibly PVT CRC or EB is detected at O on side A (respectively B);

- locate the fault in portion 1, 2, 3 or 4 (respectively in portion 9, 10, 11 or 12) of the line, i.e. either upstream of the first customer site (respectively on the side of the second client site), or between the first client site (respectively the second client site); and the central site when a fault type VT error is detected at O on side A (respectively B); - locate the fault in section 13 or 14

(respectively in section 5 or 6) of the line, i.e. upstream or downstream of the first transmission equipment after the central site when an S5 type fault is detected at O on side A ( respectively B); locate the fault in section 15 (respectively in section 7) of the line, i.e. downstream of the last transmission equipment after the central site when a fault of type S6 is detected at O on the side of the second A (respectively B); ; locate the fault in portion 16, (respectively in portion 8) of the line, when an IAD type fault is detected at O on side A (respectively B); - locate the fault in section 9, 10, 11,

12, 13, 14, 15, 16, (respectively in the portion 1, 2, 3, 4, 5, 6, 7, 8) of the line, i.e. end-to-end between the second client site and the first client site and the second client site when a bit-e type fault is detected at O on side A (respectively B.

As mentioned above, the method according to the invention also makes it possible to qualify relevant information to calculate at least one quality and / or performance criterion for this purpose.

(see FIG. 2): a- an acquisition step 30 consisting in collecting, dating and synchronizing anomaly and fault information at the level of the probes, then in sorting and isolating the incoming information, the outgoing information and the end information - at the end, then to record this information in a buffer memory 32. b - a test step 34 consisting in checking whether an incoming information generates an end-to-end information and / or an outgoing information; c- a correlation step 36 consisting in repositioning in time the incoming information in one direction and their consequent actions on the end-to-end information circulating in the opposite direction then in calculating at least one parameter representative of the quality and / or performance of the network or part of it; d- a validation step 40 of the relevance of the information at each of the preceding steps; e- a step 42 for processing information.

Note that at each of the preceding steps, there is a synchronization 44 of the calendar clocks of the probes as well as a resynchronization of the events during the communication. Thus, to carry out the acquisition step 30, the probes are synchronized on the frame of the data exchanged between the remote devices A and B. The information collected is then processed within the meaning of the standard in force before being recorded in the buffer memory 32. Said buffer memory 32 is then managed so as to compensate for the response time of the remote devices A and B and the propagation time data in the LL loop.

As illustrated in FIG. 4, the test step 34 consists in verifying whether an incoming item of information from A to O (respectively from B to O) of fault type is correlable with end-to-end item of information from B to A (respectively from A to B) and / or outgoing information. Following this test, incoming fault type information will be qualified if it is correlable with end-to-end information and will not be qualified otherwise.

The parameters used to represent the quality and performance of the network depend on the bit error rate transmitted and / or the propagation time and / or the performance of the telecommunications network. As an example, the ITU-T standard G.826 defines the parameter K _(CD) representative of the availability of the link between the two points C and D by the difference between the parameter K _(c) , representative of the availability at point C and the parameter K _(D) , representing availability at point D: K ( _CD ) ⁼ (c) - K _(D)

The calculation of K _(CD) makes it possible to highlight the inconsistencies that affect communication across the network 2.

According to an important characteristic of the process according to the invention, these inconsistencies are classified into four categories IA, IB, IC and ID. The inconsistency will be of type IA if the information is not qualified in test step 30, of type IB if the difference in QoS K _(CD) is negative between two points of the same LL, of type IC if Simultaneous information flows in both directions of transmission, and of the ID type in the event of desynchronization. In the case of an inconsistency of type IA, by assumption, the terminal loops the information. The probable causes of such an inconsistency are either a lack of simultaneity in the two directions of transmission of the link which has the effect of masking the information looped, or the fact that "m" seconds disturbed in a direction of transmission correspond to "m +/- l" seconds disturbed in the other direction or the fact that the probes provide false information. The method according to the invention makes it possible to determine that the probe provides false information if, on the one hand, there is no presence of a simultaneous fault in the two directions of transmission of the link, and on the other hand, if "m" seconds disturbed in one direction are not correlable with " m +/- l "seconds disturbed in the other direction.

In the case of a type IB inconsistency, by hypothesis the probe does not supervise the physical layer.

The probable causes of such an inconsistency are verified by the probes and can be either a non-compliance with the engineering rules, or the fact that "m" seconds disturbed in a direction of transmission correspond to "m +/- l" seconds disturbed in the other direction or the fact that the probes provide false information. In this case, the method according to the invention makes it possible to deduce that the engineering rules are not respected or that the probes provide "false" information.

The probable causes of an IC type inconsistency are either a break in the link which is detected by the probes, or that the link is faulty in both directions. This is also detected by the probes.

In this case, the information is not eligible.

ID type inconsistencies can be due to a detection fault at the level of the probes or to a breakdown in access to the server.

In this case, the server detects its anomalies and the information is not eligible. The information processing step 42 makes it possible to manage the alarms at the level of the equipment, network and service layers. The result of these treatments is then presented in the form of a dashboard, for example made available to operators.

Claims

1. Method for qualifying information and helping to locate faults in a digital telecommunications network comprising a plurality of transmission equipment arranged between at least a first customer site and at least a second customer site exchanging, via at least one operator site, digital data in screened or non-screened mode, each customer site being connected to the network via network-customer interface equipment capable of discriminating anomalies and / or faults originating from the site- customer or operator site, characterized in that it detects anomaly and / or fault information in the portions of the network located between customer sites, it discriminates anomalies and / or faults from the customer site or the site operator, then at least one signal representative of the type and origin of said defect is generated, then the signal generated is analyzed to deduce the origin and the nature of the anomaly and / or d u default.

2. Method according to claim 1, characterized in that, in non-screened mode, the signal generated is either a first signal SI of the SIA type (Alarm indication signal) scrambled, or a second signal S2 of the IAD type ( Distant Alarm indication signal) scrambled, i.e. a third S3 signal type IAD scrambled.

3. Method according to claim 2, characterized in that, the first signal SI is obtained by scrambling of a first sequence M1 coded on a first number ni of bits, the second signal S2 is obtained by scrambling a second sequence M2 coded on a second number n2 of bits, and the signal S3 is obtained by scrambling of a third sequence M3 coded on a third number n3 of bits.

4. Method according to claim 1, characterized in that, in raster mode, the signal generated is either a fourth signal S4 of type SIA partially modified, or a fifth signal S5 of type IAD carrying a first code, or a sixth signal S6 IAD type carrying a second code.

5. Method according to claim 4, characterized in that, the signal S4 is obtained by forcing part of the bits of an SIA signal at a logic level 1 for at least a determined time interval, the signal S5 is obtained by a first coding of a particular bit of an IAD signal, the signal S6 is obtained by a second coding of a particular bit of an IAD signal.

6. Method according to one of claims 1 to 3, characterized in that an SI signal is transmitted to the site operator when a fault of the MQS or SIA type is detected at the client interface on the client site, an S2 signal is transmitted to the operator site when an MQS type fault is detected at the network interface at the client site, and an S3 signal is transmitted to the operator site when a fault Of type SIA is detected at the network interface on the client site.

7. Method according to claim 6, characterized in that, the anomaly and / or fault information collected on each side of the operator-client demarcation point is detected, said information is synchronized and an SIA signal is transmitted on the client side '' at least one of the SIA or SI Missing Signal (MQS) type faults is detected on the network interface on the customer site.

8. Method according to claim 3, characterized in that the step of locating the fault consists in:

- inhibit signals of type S2 or S3 on the side of one of the client sites when a fault of another type is detected on the side of the other client site; locate the fault in the first (respectively second) customer site when an SI type fault is detected on the side of the first (respectively second) customer site; locate the fault upstream of the last transmission equipment before the central site when an SIA type fault is detected on the side of the first (respectively second) customer site; locate the fault downstream of the last transmission equipment before the central site when an MQS type fault or HDB3 error is detected on the side of the first (respectively second) customer site; locate the fault upstream of the last transmission equipment after the central site when a S2 type fault is detected on the side of the second (respectively first) customer site; - locate the fault downstream of the last transmission equipment after the central site when an S3 type fault is detected on the side of the second (respectively first) customer site.

9. Method according to claim 4, characterized in that an alarm signal S4 is generated on the side of the site operator when one of the faults of the MQS, SIA type, or of the Frame Lock Loss (PVT) type ) is detected on the client interface of the client site, a Remote Anomaly Indication (IAD) signal is transmitted on the operator site side only when no MQS, SIA or PVT type fault is detected on the network interface of the client site, we force signals of type S5 or S5 to zero on the client interface of the client site, we force a signal of type SIA on the client interface of the client site when one of the type defects

MQS, SIA, or Frame Lock Loss type

(PVT) is detected on the network interface of the customer site, an S5 type alarm signal is generated on the operator site side when an SIA or PVT type fault is detected on the network interface of the customer site , an S6 type alarm signal is generated on the site operator side when an MQS type fault is detected on the network interface of the customer site, and a possible IAD type signal is inhibited on the site operator side when a fault MQS, SIA or PVT type is detected on the client interface of the client-site.

10. Method according to claim 9, characterized in that the anomaly and fault information are synchronized and dated at a centralized point at the site operator, and an SIA type alarm signal is generated on the side of the first client site when one of the MQS, SIA, PVT or S4 type faults is detected on the side of the second client site, an SIA type alarm signal is generated on the side of the second client site when one MQS, SIA, PVT or S4 type faults are detected on the side of the first client site.

11. Method according to claim 10, characterized in that the fault location on the side of the first (respectively second) customer site consists in:

- inhibit signals of the IAD, S5 or S6 type on one side of the client sites when a fault of another type is detected on the side of the other client site; - locate the fault upstream of the first customer site (respectively the second), when an S4 type fault is detected on the side of the first customer site (respectively of the second customer site); locate the fault upstream of the last transmission equipment before the central site when an AIS type fault is detected on the side of the first customer site (respectively on the side of the second customer site); locate the fault downstream of the last transmission equipment before the central site when an MQS type fault or HDB3 error is detected on the side of the first client site (respectively on the side of the second client site); locate the fault between the first client site (respectively the second client site) and the central site when a PVT type fault or possibly PVT CRC or EB is detected on the side of the first client site (respectively on the side of the second client site);

- locate the fault either upstream of the first customer site (respectively on the side of the second customer site), or between the first customer site (respectively the second customer site) and the central site when a fault of the Error type VT is detected on the side of the first client site (respectively on the side of the second client site);

- locate the fault upstream or downstream of the first transmission equipment after the central site when an S5 type fault is detected on the side of the second customer site (respectively on the side of the first customer site); locate the fault downstream of the last transmission equipment after the central site when a S6 type fault is detected on the side of the second customer site (respectively on the side of the first customer site);

- locate the "end-to-end" fault between the second client site and the first client site (respectively between the first client site and the second client site) when a bit-e type fault is detected on the side of the second client site (respectively on the side of the first client site).

12. Method for qualifying the relevant information for calculating at least one quality and / or performance criterion in a digital telecommunication network (2), characterized in that it comprises: a- an acquisition step (30) consisting collect, date and synchronize fault and fault information at at least one point on the network, then sort and isolate incoming information, outgoing information and end-to-end information, then record this information in a buffer memory (32); b- a test step (34) consisting in checking whether an incoming information item generates end-to-end information and / or an outgoing item of information; c- a correlation step (36) consisting in repositioning in time the incoming information in one direction and their consequent action on the end-to-end information circulating in the opposite direction then in calculating at least one parameter representative of the quality and / or performance of the network or part of it; d- a validation step (40) of the relevance of the information at each of the previous steps; e- a processing step (42) of the information validated in the previous step.

13. The method as claimed in claim 12, characterized in that the test step (34) consists in checking whether an incoming piece of information from A to C (respectively - from B to C) of defect type is correlable with end-to-end information from B to A (respectively from A to B) and / or outgoing information.

14. Method according to claim 13, characterized in that an incoming fault type information will be qualified if it is correlable with end-to-end information and will not be qualified otherwise.

15. The method of claim 11, characterized in that the repositioning in time of the incoming information in one direction and their consequent action on the end-to-end information flowing in the opposite direction consists in managing the buffer memory (32) so as to compensate for the response time of the remote devices and the propagation time of the data in the LL loop.

16. Method according to one of claims 11 to

15, characterized in that the parameters representative of the quality and / or performance of the network (2) depend on the bit error rate transmitted and / or the propagation time and / or the performance of said network.

17. Method according to any one of claims 1 to 11, characterized in that it further comprises: a- an acquisition step (30) consisting in collecting, dating and synchronizing information on anomalies and faults in at least one point on the network, then sorting and isolating the incoming information, the outgoing information and the end-to-end information, then recording this information in a buffer memory (32); b- a test step (34) consisting in checking whether an incoming information item generates end-to-end information and / or an outgoing item of information; c- a correlation step (36) consisting in repositioning in time the incoming information in one direction and their consequent action on the end-to-end information circulating in the opposite direction then in calculating at least one parameter representative of the quality and / or performance of the network or part of it; d- a validation step (40) of the relevance of the information at each of the previous steps; e- a processing step (42) of the information validated in the previous step.

18. System for qualifying information and helping to locate faults in a digital telecommunications network comprising a plurality of transmission equipment arranged between at least one first customer site and at least one second customer site exchanging, via at least one operator site, digital data in raster or non-raster mode, each client site being connected to the network via network-client interface equipment, said system being characterized in that each interface equipment client network includes means capable of discriminating between anomalies and / or faults originating from the client site or the site operator, means for generating at least one signal representative of the type and origin of said defect, means for analyzing the signal generated so as to deduce therefrom the origin and the nature of the anomaly and / or the default.