CN111586504A - Service-based same-route analysis method for communication operator - Google Patents

Abstract

The invention discloses a service-based same-route analysis method for a communication operator, which aims at the defect that a network management system of a transmission device only has logical topology networking display and combines the condition of real physical route of a pipeline system to automatically judge whether the same-route condition among network layers exists or not when the service is opened and configured. The method and the system can comprehensively screen the light path configuration of the opened service, judge whether the system has the same routing condition among the cross-network levels, correct the same routing condition among the cross-network levels, and improve the safety of the transmission network for service bearing. Meanwhile, the networking of the newly added equipment is standardized, and the configuration of the new service is opened. And whether the newly opened service has the same routing condition among the cross-network levels or not is carried out, and if the newly opened service has the same routing condition among the cross-network levels, other routes are reselected to configure the service. Thereby avoiding the occurrence of co-routing situations across network levels.

Description

Service-based same-route analysis method for communication operator

Technical Field

The invention relates to the technical field of communication resource management, in particular to a service-based same-route analysis method for a communication operator.

Background

Fiber resources are an important component of the basic network resources of three large communication operators. With the continuous development of services and the continuous evolution of technologies such as 3G, 4G, FTTH, the size of services carried by the transport networks of three operators is also continuously increasing. In order to guarantee the service quality and improve the service experience of the user, the security of the transport network of the operator needs to be strictly guaranteed.

At present, the transport bearer network system of a domestic operator mainly includes a traditional wavelength division device network, an OTN device network, an IPRAN device network, a PTN device network, an SDH device network, and an optical cable network for networking of transmission devices. The device networking is mainly annular networking and is divided into a core layer, a convergence layer and an access layer according to network level device networking. In the design and construction process of each level networking, optical cables in the same route are avoided as much as possible to carry out bearing networking. However, in the network management system of the transmission device, when the end-to-end configuration is performed on the service, the service path needs to pass through the access layer, the convergence layer, and the core layer. However, in service configuration, the physical route of the optical cable carrying the device networking is not clear in the transmission device network management system, and although the same route is avoided in the same-level loop networking, the same route between different levels may exist. For example: the convergence layer route in the main service direction and the core layer route in the standby direction form the same route. This constitutes a safety hazard.

The existing optical fiber resource management system is essentially a static ledger system based on a table, resource data is manually input, and the manual input is based on completion data of a project. The optical fiber resource of the engineering site is marked as a paper label, and a small amount of information is recorded.

The fiber resource management system in the prior art has the following defects:

in the existing pipeline system platform, the same routing condition of equipment networking of the same network level can be judged, but the same routing condition of different network levels cannot be judged, so that automatic judgment of the same routing between different network levels is realized, service configuration in a network management system of the transmission equipment is guided, the occurrence of the same routing condition between different network levels cannot be avoided, and potential safety hazards exist in the network.

Disclosure of Invention

The present invention is directed to provide a service-based co-route analysis method for a communications carrier, so as to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: a service-based co-route analysis method for communication operators comprises the following steps:

when each optical path is queried, all carriers are assigned to obtain a real-time primary fault mark value Z1 and a standby fault mark value B1, absolute difference values of the primary fault mark value Z1 and the standby fault mark value B1 are compared, f is | Z1-B1|, a standard value f0 is set, and if f is less than f0, the positions of the carriers on the primary optical path Z and the standby optical path B need to be judged to determine whether the same well or the same electric pole exists or not;

if f is greater than or equal to f0, the primary optical path Z and the backup optical path B do not need to be determined, and no fault point exists, and by comparing the information of the carrying objects of the primary optical path and the backup optical path, if the carrying objects with the same ID are found, the situation that the primary optical path and the backup optical path have the same route is indicated, so that the fault is determined.

Further, setting a main optical path Z and a standby optical path B, respectively calculating a main fault mark value Z0 and a standby fault mark value B0, setting a specific assignment for a specific bearing object on a specific certain optical path and a specific optical cable, setting a cross connecting box value on each optical cable value, setting a starting cross connecting box value to be 1, a second cross connecting box value to be 2 and an Nth cross connecting box value to be N according to an optical transmission sequence, wherein all cross connecting boxes are included in the setting process;

setting a pipeline value for the pipeline on each optical cable, wherein a first well value is set to be 1, a second well value is set to be 2, a third well value is set to be N according to an optical transmission sequence, and all wells are included in the setting;

set for pole way value on each optical cable, according to the optical transmission order, the setting value is 1 on the first pole, and the second pole setting value is 2, and the Nth pole setting value is N, contains all poles when setting for.

Further, for each corresponding optical path junction box, the transmission may be a break point or a continuous point in an actual pipeline according to a specific optical path; in an actual pipeline, the pipeline may be a discontinuous point and may be a continuous point; in an actual pipeline, the electric pole may be a discontinuous point, and may be a continuous point.

Further, calculating a main fault mark value, acquiring a calculated value KL of the optical cable cross-connecting cabinet during calculation,

KL＝J01+J02+J03+……+J0N (1)

in the formula, J01 represents a first distribution box value in actual use, J0 represents a second distribution box value in actual use, J03 represents a first distribution box value in actual use, and J0N represents a last distribution box value in actual use.

Further, a main fault mark value is calculated, during calculation, a pipeline calculation value KD1 is obtained,

KD1＝D01+D02+D03+……+D0N (2)

in the formula, D01 represents the first well value in actual use, D0 represents the second well value in actual use, D03 represents the third well value in actual use, and D0N represents the last well value in actual use.

Further, the main fault mark value is calculated, and during calculation, the pole calculation value KD2 is obtained,

KD2＝d01+d02+d03+……+d0N(3)

in the equation, d01 represents the second pole value in actual use according to the first pole value d0 in actual use, d03 represents the third pole value in actual use, and d0N represents the last pole value in actual use.

Further, the primary failure flag value Z1 is obtained as KL + KD1+ KD2 (4).

Further, obtaining a standby fault mark value B1, obtaining a calculated value EL of the optical cable cross-connecting box,

EL＝J01+J02+J03+……+J0N (5)

wherein J01 represents a first distribution box value in actual use, J0 represents a second distribution box value in actual use, J03 represents a first distribution box value in actual use, and J0N represents a last distribution box value in actual use;

specifically, the backup failure flag value B1 is taken, and when calculating, the calculated value ED1 of the pipeline is obtained,

ED1＝D01+D02+D03+……+D0N (6)

wherein D01 represents a first well value in actual use, D0 represents a second well value in actual use, D03 represents a third well value in actual use, and D0N represents a last well value in actual use;

obtaining a standby fault mark value B1, obtaining a pole calculation value ED2 during calculation,

ED2＝d01+d02+d03+……+d0N (7)

in the formula, d01 represents the second pole value at the time of actual use in accordance with the first pole value d0 at the time of actual use, d03 represents the third pole value at the time of actual use, and d0N represents the last pole value at the time of actual use;

the primary fault flag value B1 is EL + ED1+ ED2 (8).

Further, a service type matrix Y (a, G, L, X, D1, D2, J) is stored, where a represents a corresponding service number, G represents a corresponding optical path information matrix, L represents a corresponding optical cable information matrix, X represents a corresponding cross-connection box information matrix, D1 represents a corresponding pipeline information matrix, D2 represents a corresponding pole information matrix, and J represents a corresponding machine room information matrix.

Further, setting an optical path information matrix G and storing information of each optical path, wherein the optical path information matrix G comprises G (G1, G2, G3 and G4), G1 represents an optical path name, G2 represents a network element port in a specific optical path, G3 represents optical path jumper information, G4 represents associated optical cable information, all associated optical cables are connected according to a pipeline jumper sequence and the lengths are calculated, and the associated optical cables are calculated according to map coordinates;

a cable information matrix L is set, which includes L (L1, L2, L3, L4, L5, L6), where L1 denotes a cable name, L2 denotes cable start point information, L3 denotes cable end point information, L4 denotes the number of cores, L5 denotes core information, a system writes a pipe carried by each core, and L6 denotes a belonging pipe or rod.

The invention assigns values to each bearing object on the main optical path Z and the standby optical path B, and performs equal quantization summation processing, so that the main fault marking value Z1 and the standby fault marking value B1 are assigned and compared in advance when in actual use, the actual possible fault condition is determined, and then the ID information is obtained according to the geographical position identification, and the program resource is saved. The analysis method is combined with the existing pipeline resource management system, and core position and ODF information of the starting point, the intermediate jump point and the end point of the optical path can be inquired when each optical path is inquired.

The same route in the invention refers to: in the main end-to-end route and the standby end-to-end route of the service, one or more sections of routes are loaded by different optical cables in the same optical cable or the same section of pipeline, the same well, the same optical cross-connecting box, the same lead, the same supporting point, the same machine room, the same pole or the same pole. Therefore, judging whether the same route exists between different network layers is essentially the case of judging whether the same route exists in the end-to-end route of the service.

By combining the existing pipeline resource management system, when each optical path is queried, the core position and ODF information of the starting point, the intermediate jump point and the end point of the optical path can be queried, the optical cable section information associated with the ODF terminal can be queried in the ODF information query, and the pipeline section information and the rod section information associated with the optical cable section can be queried in the optical cable section information query, so that one optical path information can be associated with one group of optical cable section information and one group of pipeline section and rod section information, and the optical cable section information, the pipeline section information and the rod section information are all provided with unique IDs for identification. When one service configures the active-standby protection, by comparing the information of the optical cable segment group, the pipeline segment group, the rod segment group and the like of the active optical path and the standby optical path, if the optical cable segment, the pipeline segment or the rod segment with the same ID is found, the situation that the active-standby optical path has the same route is indicated.

The invention has the following advantages: the automatic judgment of the same route between different network levels from end to end based on the service is realized, and the potential safety hazard of the network is avoided. The advancement is realized in the following 2 aspects:

1. the optical path configuration of the opened service is comprehensively screened, whether the system has the same routing condition among the network-crossing levels is judged, the same routing condition among the network-crossing levels is rectified, and the safety of the transmission network for service bearing is improved;

2. and standardizing networking of newly added equipment and opening and configuring new services. And whether the newly opened service has the same routing condition among the cross-network levels or not is carried out, and if the newly opened service has the same routing condition among the cross-network levels, other routes are reselected to configure the service. Thereby avoiding the occurrence of co-routing situations across network levels.

Aiming at the defect that a network management system of transmission equipment only has logical topology networking display, the situation of real physical routing of a pipeline system is combined, whether the same routing situation among network layers exists during service opening configuration is automatically judged, and the following aims are achieved.

(1) The optical path configuration of the opened service is comprehensively screened, whether the same routing condition exists among the cross-network levels in the system is judged, the same routing condition existing among the cross-network levels is rectified, and the safety of the transmission network for service bearing is improved.

(2) And standardizing networking of newly added equipment and opening and configuring new services. And whether the newly opened service has the same routing condition among the cross-network levels or not is carried out, and if the newly opened service has the same routing condition among the cross-network levels, other routes are reselected to configure the service, so that the occurrence of the same routing condition among the cross-network levels is avoided.

Drawings

Fig. 1 is a schematic diagram of an implementation process of a service-based co-route analysis method for a communications carrier according to the present invention;

fig. 2 is a schematic structural diagram of a service-based co-route analysis system of a communication carrier according to the present invention;

fig. 3 is a logic diagram of a software implementation of the service-based co-route analysis system of a communication carrier according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Fig. 1 is a schematic diagram illustrating an implementation process of a service-based same route analysis method for a communication carrier according to the present invention; fig. 2 is a schematic structural diagram of a service-based co-route analysis system of a communication carrier according to the present invention;

the analysis system of the embodiment comprises:

the pipeline system is used for importing dummy resource data into the dummy resource module and modifying the pipeline system data in batches through the dummy resource module to enable the data to be accurate;

the field check module checks through the key points, calibrates the dummy resource data and transmits the dummy resource data to the dummy resource module;

the gateway system imports service configuration data into the service module;

the cross-layer same-route automatic judgment module is used for judging and opening new services, so that the same route caused by network management service configuration is avoided;

and the cross-layer same-route automatic judgment module is communicated with the dummy resource module to calibrate the route information.

The above-mentioned path of the communication carrier of this embodiment has a main analysis structure.

Fig. 3 is a logic diagram of a software implementation of the service-based co-route analysis system of a communication carrier according to the present invention;

the storage service module in the pipeline system is used for coding and summarizing various types of services, and a service type matrix Y (A, G, L, X, D1, D2 and J) is stored in the storage service module, wherein A represents a corresponding service number, G represents a corresponding optical path information matrix, L represents a corresponding optical cable information matrix, X represents a corresponding cross-connecting box information matrix, D1 represents a corresponding pipeline information matrix, D2 represents a corresponding rod information matrix, and J represents a corresponding machine room information matrix.

Specifically, each parameter is defined in the service module, wherein a service name is set, and each name is set according to an actual element and is imported through a network management interface or a table; each port network element is imported from a network management interface or a table, and a plurality of network element ports exist and are displayed in a list form.

Specifically, in this embodiment, an optical path information matrix G is set and information of each optical path is stored, where the optical path information matrix G includes equations G (G1, G2, G3, G4), G1 indicates an optical path name, G2 indicates a network element port in a specific optical path, G3 indicates optical path jumper information, and G4 indicates associated optical cable information, and all associated optical cables are connected in a pipeline jumper order and calculated in length, where the associated optical cables are calculated in map coordinates.

Specifically, the cable information matrix L includes L (L1, L2, L3, L4, L5, L6), where L1 denotes a cable name, L2 denotes cable start point information, L3 denotes cable end point information, L4 denotes the number of cores, L5 denotes core information, a system writes a pipeline carried by each core, and L6 denotes a belonging pipe or rod.

Specifically, the junction box information matrix X includes X (X1, X2, X3, X4, X5, X6, X7, and X8), where X1 denotes a light intersection name, X2 denotes a coordinate, X3 denotes an address, X4 denotes a capacity, X5 denotes a level, X6 denotes an affiliated integrated service area, X7 denotes terminal details, and X8 denotes a bound electronic tag.

Specifically, the pipeline information matrix D1 includes D1(D11, D12, D13, D14, D15), where D11 represents a pipeline name, D12 represents a start well and an end well, D13 represents the number of pipe holes, and D14 represents pipe hole information, and different pipe hole information corresponds to different cable information. And setting a well name, well coordinates, associated pipeline data, associated optical cable data and a binding electronic tag corresponding to the well of the pipeline.

Specifically, the route information matrix D2 includes D2(D21, D22, D23, D24), where D21 denotes a route name, D22 denotes route coordinates including a route start point coordinate and a route end point coordinate, D23 denotes a start pole and an end pole, and D24 denotes an associated optical cable.

Specifically, the room information matrix J includes J (J1, J2, J3, J4, J5), where J1 represents a room name, J2 represents room coordinates, J3 represents an address, J4 represents a binding tag, and J5 represents a device list.

Specifically, the fault determination process in the embodiment of the present invention is shown by an arrow in the figure, and obtains the optical cable fault location through the change of the optical path information, where the optical cable fault location is calculated by taking a single optical cable as a unit and is calculated by taking the optical path whole-course adjustment route as a unit, and the calculation is performed by taking the optical cable reel length at the end equipment, the well, and the electric pole into consideration and correcting the optical cable reel length. After a starting point of fault positioning is selected and a fault distance measured by well OTDF is input, the system automatically calculates the distance, and the calculating process is as follows: and subtracting the length of the optical cable map marking each section by the input fault distance section by section, adding from the starting point, subtracting a disc factory from each terminal equipment and each electric pole and well, and correcting to obtain the value of 0, wherein the positioning is finished. And (4) dividing an area according to a set radius by using a positioning point to prompt faults.

Specifically, when a service route is analyzed, the information of the carriers of the main optical path and the standby optical path is compared, if the carriers with the same ID are found, the situation that the main optical path and the standby optical path have the same route is indicated, and for the main optical path Z and the standby optical path B, corresponding information is respectively obtained, an optical cable path is displayed, a pipeline or pole path is displayed, and a passing well or an electric pole is displayed; judging whether the same route has the same well or the same electric pole by taking the electric pole and the well as the unique judgment value; and pipelines, pole lines and optical cable sections with the same hidden danger of routing, and electric poles and wells with hidden dangers are displayed on the map.

Specifically, the service type matrix Y (a, G, L, X, D1, D2, J) in the embodiment of the present invention can query information of a pipeline, a well, an optical cross-connection box, a lead-up, a supporting point, a machine room, a pole, and a pole-road bearing object associated with an optical cable segment, any piece of optical path information can be associated with detailed information of all bearing objects, and the bearing object information has a unique ID for identification; when one service configures the main and standby protection, the information of the carrying objects of the main optical path and the standby optical path is compared, and if the carrying objects with the same ID are found, the condition that the main and standby optical paths have the same route is indicated, so that the fault is judged to exist.

Specifically, in this embodiment, a primary optical path Z and a backup optical path B are set, and a primary failure flag value Z0 and a backup failure flag value B0 are calculated respectively, in this embodiment, specific assignments are set for a specific optical path and a specific bearing object on a specific optical cable, for example, a first optical cable value is set to be 1, a second optical cable value is 2, an nth optical cable value is N on the first optical cable value, and a cross-connect box value is set on the first optical cable value, where on each optical cable, according to an optical transmission sequence, a starting cross-connect box setting value is 1, a second cross-connect box setting value is 2, an nth cross-connect box setting value is N, and all cross-connect boxes are included in the setting process; setting a pipeline value for the pipeline on each optical cable, wherein a first well value is set to be 1, a second well value is set to be 2, a third well value is set to be N according to an optical transmission sequence, and all wells are included in the setting; set for pole way value on each optical cable, according to the optical transmission order, the setting value is 1 on the first pole, and the second pole setting value is 2, and the Nth pole setting value is N, contains all poles when setting for. For each corresponding optical path junction box, according to the specific optical path transmission, in the actual pipeline, there may be a discontinuity point, and there may be a continuous point, such as the first junction box, the second junction box, and the fourth junction box, or there may be the first junction box, the third junction box, and the fifth junction box. In the same way, in the actual pipeline, the pipeline can be a continuous value and also can be an interrupted value, and in the actual pipeline, the electric pole in the same way can be a continuous value and also can be an interrupted value.

Specifically, a main fault mark value is calculated, during calculation, a calculation value KL of the optical cable cross connecting cabinet is obtained,

KL＝J01+J02+J03+……+J0N (1)

in the formula, J01 represents a first distribution box value in actual use, J0 represents a second distribution box value in actual use, J03 represents a first distribution box value in actual use, and J0N represents a last distribution box value in actual use.

In this embodiment, during actual use, the light path may be a discontinuous value, and may be all preset pipeline values, and the actual calculated value KL of the optical cable cross connecting cabinet is calculated according to the result. Such as 1+2+3+ 4-10, 1+3+5+ 7-16.

Specifically, the main fault flag value is calculated, and during calculation, the pipeline calculation value KD1 is obtained,

KD1＝D01+D02+D03+……+D0N (2)

in the formula, D01 represents the first well value in actual use, D0 represents the second well value in actual use, D03 represents the third well value in actual use, and D0N represents the last well value in actual use.

In this embodiment, during actual use, the light path may be a discontinuous value, and may be all preset pipeline values, and the actual well calculation value KL is calculated according to the result. Such as 1+2+3+ 4-10, 1+3+5+ 7-16.

Specifically, the main fault mark value is calculated, and during calculation, the pole calculation value KD2 is obtained,

KD2＝d01+d02+d03+……+d0N (3)

in the equation, d01 represents the second pole value in actual use according to the first pole value d0 in actual use, d03 represents the third pole value in actual use, and d0N represents the last pole value in actual use.

In this embodiment, during actual use, the light path may be a discontinuous value, and may be all preset pipeline values, and the actual well calculation value KL is calculated according to the result. Such as 1+2+3+ 4-10, 1+3+5+ 7-16.

The primary fault flag value Z1 is KL + KD1+ KD2(4)

Similarly, obtaining a standby fault mark value B1, obtaining a calculated value EL of the optical cable cross connecting cabinet,

EL＝J01+J02+J03+……+J0N (5)

in the formula, J01 represents a first distribution box value in actual use, J0 represents a second distribution box value in actual use, J03 represents a first distribution box value in actual use, and J0N represents a last distribution box value in actual use.

In this embodiment, during actual use, the light path may be a discontinuous value, and may be all preset pipeline values, and the actual calculated value EL of the optical cable cross-connecting cabinet is calculated according to the result.

Specifically, the backup failure flag value B1 is taken, and when calculating, the calculated value ED1 of the pipeline is obtained,

ED1＝D01+D02+D03+……+D0N (6)

in the formula, D01 represents the first well value in actual use, D0 represents the second well value in actual use, D03 represents the third well value in actual use, and D0N represents the last well value in actual use.

In this embodiment, in actual use, the light path may be a discontinuous value, and may be all preset pipe values, and the actual well calculation value EL is calculated according to the result. Specifically, the standby fault flag value B1 is taken, and at the time of calculation, the pole calculation value ED2 is obtained,

ED2＝d01+d02+d03+……+d0N (7)

in the equation, d01 represents the second pole value in actual use according to the first pole value d0 in actual use, d03 represents the third pole value in actual use, and d0N represents the last pole value in actual use.

In this embodiment, in actual use, the light path may be a discontinuous value, and may be all preset pipe values, and the actual well calculation value EL is calculated according to the result.

The primary fault flag value B1 ═ EL + ED1+ ED2(8)

Acquiring a real-time primary fault marking value Z1, comparing the primary fault marking value Z1 with a standby fault marking value B1 by taking the absolute difference value f ═ Z1-B1|, setting a standard value f0, and if f is less than f0, judging the positions of the carriers on the primary optical path Z and the standby optical path B to determine whether the same well or the same electric pole exists or not;

if f is equal to or greater than f0, the primary optical path Z and the backup optical path B do not need to be determined, and no failure point exists.

Specifically, the present invention assigns values to each of the bearers on the primary optical path Z and the backup optical path B, and performs an equi-quantitative summation process, so that the primary fault flag value Z1 is compared with the backup fault flag value B1 in advance to determine a possible actual fault condition, and then the ID information is obtained according to the geographical location identifier, thereby saving program resources. The analysis method is combined with the existing pipeline resource management system, and core position and ODF information of the starting point, the intermediate jump point and the end point of the optical path can be inquired when each optical path is inquired.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. A method for service-based co-route analysis for a communications carrier,

when each optical path is queried, all carriers are assigned to obtain a real-time primary fault mark value Z1 and a standby fault mark value B1, absolute difference values of the primary fault mark value Z1 and the standby fault mark value B1 are compared, f is | Z1-B1|, a standard value f0 is set, and if f is less than f0, the positions of the carriers on the primary optical path Z and the standby optical path B need to be judged to determine whether the same well or the same electric pole exists or not;

if f is greater than or equal to f0, the primary optical path Z and the backup optical path B do not need to be determined, and no fault point exists, and by comparing the information of the carrying objects of the primary optical path and the backup optical path, if the carrying objects with the same ID are found, the situation that the primary optical path and the backup optical path have the same route is indicated, so that the fault is determined.

2. The method of claim 1, wherein the primary optical path Z and the backup optical path B are set, the primary failure flag value Z0 and the backup failure flag value B0 are calculated, the specific assignment is set for a specific optical path and a specific bearer on a specific optical cable, a cross-connect box value is set for each optical cable, the starting cross-connect box is set to 1, the second cross-connect box is set to 2, the nth cross-connect box is set to N according to the optical transmission sequence, and all cross-connect boxes are included in the setting process;

setting a pipeline value for the pipeline on each optical cable, wherein a first well value is set to be 1, a second well value is set to be 2, a third well value is set to be N according to an optical transmission sequence, and all wells are included in the setting;

set for pole way value on each optical cable, according to the optical transmission order, the setting value is 1 on the first pole, and the second pole setting value is 2, and the Nth pole setting value is N, contains all poles when setting for.

3. The method of claim 2, wherein for each corresponding distribution box, the distribution box transmits according to a specific optical path, and in an actual pipeline, the distribution box may be a break point or a continuous point; in an actual pipeline, the pipeline may be a discontinuous point and may be a continuous point; in an actual pipeline, the electric pole may be a discontinuous point, and may be a continuous point.

4. The service-based co-route analysis method of a communication carrier according to claim 2, wherein the primary failure flag value is calculated, and in the calculation, the calculated value KL of the optical cable cross-connecting cabinet is obtained,

KL＝J01+J02+J03+……+J0N (1)

in the formula, J01 represents a first distribution box value in actual use, J0 represents a second distribution box value in actual use, J03 represents a first distribution box value in actual use, and J0N represents a last distribution box value in actual use.

5. A service-based co-route analysis method for communication carriers according to claim 4, wherein the primary failure flag value is calculated, and in the calculation, a pipe calculation value KD1 is obtained,

KD1＝D01+D02+D03+……+D0N (2)

in the formula, D01 represents the first well value in actual use, D0 represents the second well value in actual use, D03 represents the third well value in actual use, and D0N represents the last well value in actual use.

6. The traffic-based co-routing analysis method for communication carriers of claim 5, wherein the primary failure flag value is calculated, and in the calculation, the pole calculation value KD2 is obtained,

KD2＝d01+d02+d03+……+d0N (3)

in the equation, d01 represents the second pole value in actual use according to the first pole value d0 in actual use, d03 represents the third pole value in actual use, and d0N represents the last pole value in actual use.

7. The traffic-based co-route analysis method for communication carriers of claim 6,

and acquiring a main fault flag value Z1 which is KL + KD1+ KD2 (4).

8. The traffic-based co-routing analysis method for communications carriers of claim 2, wherein obtaining the backup failure flag value B1, obtaining the cable splice closure calculation value EL,

EL＝J01+J02+J03+……+J0N (5)

wherein J01 represents a first distribution box value in actual use, J0 represents a second distribution box value in actual use, J03 represents a first distribution box value in actual use, and J0N represents a last distribution box value in actual use;

specifically, the backup failure flag value B1 is taken, and when calculating, the calculated value ED1 of the pipeline is obtained,

ED1＝D01+D02+D03+……+D0N (6)

wherein D01 represents a first well value in actual use, D0 represents a second well value in actual use, D03 represents a third well value in actual use, and D0N represents a last well value in actual use;

obtaining a standby fault mark value B1, obtaining a pole calculation value ED2 during calculation,

ED2＝d01+d02+d03+……+d0N (7)

in the formula, d01 represents the second pole value at the time of actual use in accordance with the first pole value d0 at the time of actual use, d03 represents the third pole value at the time of actual use, and d0N represents the last pole value at the time of actual use;

the primary fault flag value B1 is EL + ED1+ ED2 (8).

9. The method as claimed in claim 2, wherein a traffic type matrix Y (a, G, L, X, D1, D2, J) is stored, wherein a represents a corresponding traffic number, G represents a corresponding optical path information matrix, L represents a corresponding optical cable information matrix, X represents a corresponding cross-connect box information matrix, D1 represents a corresponding pipe information matrix, D2 represents a corresponding pole information matrix, and J represents a corresponding machine room information matrix.

10. The traffic-based co-route analysis method for telecommunication carriers of claim 9, wherein an optical path information matrix G is set and information of each optical path is stored, wherein the optical path information matrix G includes the formula G (G1, G2, G3, G4), G1 represents an optical path name, G2 represents a network element port in a specific optical path, G3 represents optical path jumper information, G4 represents associated optical cable information, all associated optical cables are connected in a pipeline jumper order and the lengths are calculated, and the associated optical cables are calculated according to map coordinates;

a cable information matrix L is set, which includes L (L1, L2, L3, L4, L5, L6), where L1 denotes a cable name, L2 denotes cable start point information, L3 denotes cable end point information, L4 denotes the number of cores, L5 denotes core information, a system writes a pipe carried by each core, and L6 denotes a belonging pipe or rod.

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