CN115720209A - Method and system for automatic concatenation and data check of transmission network service circuit route - Google Patents

Abstract

The invention discloses a method for automatically connecting transmission network service circuit routes in series and checking data, which comprises the following steps: collecting multi-type set data of multiple manufacturers in a distributed manner, carrying out unified analysis and classification and data cleaning processing, and obtaining basic configuration cleaning processing data of the multiple manufacturers; according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route; collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data concatenation; splicing the static link relations among a plurality of manufacturers; judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set; according to the routing network communication protocol, cross-linking is the linking of different ports in the same network element, and automatic audit of serial data is carried out; the invention also discloses a system for automatic concatenation of transmission network service circuit routes and data check.

Description

Method and system for automatic concatenation and data check of transmission network service circuit route

Technical Field

The invention relates to the technical field of intelligent operation of telecommunication operation business, in particular to a method and a system for automatically connecting transmission network business circuit routes in series and checking data.

Background

At present, a transmission network is the basis of the whole communication network of an operator, a transmission line is responsible for signal transmission and signal processing of transmission equipment, and the transmission network serves various services borne by the network, such as intra-network relay services, private line services and the like of a CN2 network and a 163 network; according to the scale of a client enterprise, the business circuit networking has three main modes: 1) Within the same local network. 2) Across different local networks within the same province. 3) Spanning different provinces; the circuit networking mode spanning different provinces is the most complex; the end-to-end route of the circuit can be divided into an access section, a local section and a long distance section physically; under the advanced and stable network characteristics, the larger the spatial span of a service networking mode is, the more systems for storing the service end-to-end segmented data are; an access section: accessing equipment and a route between client equipment and first equipment of a local network segment access computer room; in this section: accessing all the devices and routes from the first device in the machine room to the first device in the trunk network; long-distance section: all devices and routes of a backbone network of a traffic path; the service end-to-end resources are unclear due to different sources of data; the manual data has multiple maintenance points and poor real-time performance; data maintenance of different routing sections of different mechanisms relates to manual maintenance of different personnel, and the data accuracy is poor; the data accuracy is poor; in the face of the current architecture design of an intelligent network, when a service fault or a channel is congested, service routes can be automatically switched, so that manual maintenance data cannot be updated in time, hidden dangers are caused to later-stage service operation, or service junk data are formed; therefore, there is a need for a method and system for automatic concatenation of traffic circuit routes and data checking in a transmission network to at least partially solve the problems of the prior art.

Disclosure of Invention

In the summary section, a series of concepts in a simplified form are introduced, which will be described in further detail in the detailed description section; this summary of the invention is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

To at least partially solve the above problems, the present invention provides a method for automatic concatenation of transmission network service circuit routes and data checking, comprising:

s100: collecting multi-type set data of multiple manufacturers in a distributed manner, carrying out unified analysis and classification and data cleaning processing, and obtaining basic configuration cleaning processing data of the multiple manufacturers;

s200: according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route;

s300: collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data serial connection; splicing the static link relations among a plurality of factories;

s400: judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set;

s500: according to the routing network communication protocol, the cross link is the link of different ports in the same network element, and the automatic audit of the serial data is carried out.

Preferably, the S100 includes:

s101: acquiring basic configuration data and basic client data of multiple manufacturers in a distributed manner, and summarizing the basic configuration data and the basic client data into multiple types of set data of the multiple manufacturers;

s102: various types of manufacturers include: a first type manufacturer, a second type manufacturer, a third type manufacturer and a fourth type manufacturer; the basic configuration data includes: network element configuration data, rack configuration data, machine frame configuration data, board configuration data, port configuration data, topology configuration data, cross configuration data, SNC configuration data, time slot configuration data and subnet configuration data;

s103: and performing unified analysis and classification and data cleaning processing on the multi-type set data of the multiple types of manufacturers to obtain cleaning processing data of basic configuration of the multiple types of manufacturers.

Preferably, the S200 includes:

s201: creating a transport network bearing relation combination; the transport network bearer relationship combination comprises: client layer routing, odu layer routing, otu layer routing, och layer routing and oms layer routing;

s202: combining the bearing relations of the transmission network, and sequentially bearing from a high order to a low order according to the bearing relations; the carrying from the high order to the low order according to the carrying relation comprises the following steps: sequentially carrying from an oms layer to an och layer to an otu layer to a client layer;

s203: carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route; the multistage transmission circuit includes: the device comprises a client layer transmission circuit, an odu layer transmission circuit, an otu layer transmission circuit, an och layer transmission circuit and an oms layer transmission circuit.

Preferably, the S300 includes:

s301: creating a plurality of segments of end-to-end routing data; the multi-segment end-to-end routing data includes: network element port data, topology data among network elements, network element internal cross data and inter-manufacturer static link resource data;

s302: carrying out end-to-end routing data concatenation on a plurality of sections of end-to-end routing data in a plurality of sections;

s303: and splicing the static link relations among a plurality of factories according to the multi-segment end-to-end routing data.

Preferably, the S400 includes:

s401: setting an auxiliary operation method, screening algorithm input parameters, inputting the algorithm input parameters into an end-to-end route splicing algorithm of the transmission circuit for operation, and obtaining an end-to-end route splicing operation result of the transmission circuit;

s402: judging whether the current inquiry path type and the end-to-end route splicing are finished or not according to the end-to-end route splicing operation result of the transmission circuit, circularly splicing the route, and recursively inquiring whether the route path reaches an oms layer or not in sequence, wherein if the route path reaches the oms layer, the end-to-end route splicing is finished, and the result is collected into an end-to-end route set; obtaining an end-to-end route splicing state;

s403: and collecting an end-to-end route set through the transmission network according to the end-to-end route splicing state.

Preferably, the S500 includes:

s501: establishing a routing network communication protocol, and cross-linking the routing network communication protocol into links of different ports in the same network element;

s502: taking a plurality of factories at any end as a starting point, and inquiring path search through the relationship among routing, topology, intersection and time slot to form an end-to-end complete path;

s503: and through an end-to-end complete path, the data feedback resources after the serial connection is successful are used for production and use, and the serial data are automatically audited.

Preferably, the S103 includes:

s1031, performing unified analysis and classification on the multi-type set data of the various manufacturers; the unified analysis and classification comprises the following steps: classifying the classified data into multi-type classified data; the multi-type classification data includes: point type data, line type data, and net type data;

s1032, the dot type data includes: the system comprises a network element, a frame, a machine frame, a board card, a port and a time slot; the line type data includes: topology, crossover, SNC and SNC routing; the net type data includes: subnet type data and client data;

and S1033, obtaining cleaning processing data of the basic configuration of the various manufacturers through data cleaning processing.

Preferably, the S203 includes:

s2031, establishing a basic multilayer route; defining each layer of route starting point and each layer of route end point of the basic multilayer route;

and S2032, taking the route end point of each layer as the starting point of the previous layer of route, and splicing the multi-layer routes of the multi-stage transmission circuit.

Preferably, the S503 includes:

s5031, through an end-to-end complete path, an end-to-end complete path content set crosses and is topologically combined, and both ends of the cross do not cross network elements;

s5032, intelligently and automatically judging whether the end-to-end path concatenation is successful; when the two ends do not meet the cross and do not span the network element, the end-to-end path fails to be connected in series, and the intelligent cycle adjustment is fed back; when the two ends of the path accord with the cross and do not cross the network element, the end-to-end path is successfully connected in series;

s5033, when the end-to-end path is successfully concatenated, the data feedback resource after the successful concatenation is used for production and use, and performing automatic audit of the concatenated data.

The invention provides a transmission network service circuit route automatic series connection and data checking system, comprising:

the system adopts the transmission network service circuit route automatic serial connection and data checking method.

Compared with the prior art, the invention at least comprises the following beneficial effects:

the invention provides a method for automatically connecting transmission network service circuit routes in series and checking data, which comprises the following steps: collecting multi-type set data of multiple manufacturers in a distributed manner, carrying out unified analysis and classification and data cleaning processing, and obtaining basic configuration cleaning processing data of the multiple manufacturers; according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route; collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data concatenation; splicing the static link relations among a plurality of manufacturers; judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set; according to the routing network communication protocol, the cross link is the link of different ports in the same network element, and the automatic audit of the serial data is carried out.

Other advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a flow chart of the transmission network service circuit route automatic concatenation and data checking method of the present invention.

Fig. 2 is a routing data concatenation diagram of the transmission network service circuit routing automatic concatenation and data checking system according to the present invention.

Fig. 3 is a serial end-to-end routing diagram of the transmission network service circuit routing automatic serial connection and data checking system according to the present invention.

Fig. 4 is a diagram of a data frame for cleaning the basic configuration of a manufacturer of a transmission network service circuit route automatic concatenation and data checking system according to the present invention.

Fig. 5 is a diagram of multi-type classified data of the transmission network service circuit route automatic concatenation and data checking system according to the present invention.

Detailed Description

The present invention is further described in detail below with reference to the drawings and examples so that those skilled in the art can implement the invention with reference to the description; as shown in fig. 1-5, the present invention provides a method for automatic concatenation and data check of transmission network service circuit routes, comprising:

s100: collecting multi-type set data of multiple types of manufacturers in a distributed manner, and performing unified analysis, classification and data cleaning processing to obtain basic configuration cleaning processing data of the multiple types of manufacturers;

s200: according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route;

s300: collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data serial connection; splicing the static link relations among a plurality of manufacturers;

s400: judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set;

s500: according to the routing network communication protocol, the cross link is the link of different ports in the same network element, and the automatic audit of the serial data is carried out.

The working principle of the technical scheme is as follows: the invention provides a method for automatically connecting transmission network service circuit routes in series and checking data, which comprises the following steps:

s100: collecting multi-type set data of multiple manufacturers in a distributed manner, carrying out unified analysis and classification and data cleaning processing, and obtaining basic configuration cleaning processing data of the multiple manufacturers;

s200: according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route;

s300: collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data concatenation; splicing the static link relations among a plurality of manufacturers;

s400: judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set;

s500: according to the routing network communication protocol, the cross link is the link of different ports in the same network element, and the automatic audit of the serial data is carried out.

The beneficial effects of the above technical scheme are: the invention provides a transmission network service circuit route automatic series connection and data checking method, which comprises the following steps: collecting multi-type set data of multiple types of manufacturers in a distributed manner, and performing unified analysis, classification and data cleaning processing to obtain basic configuration cleaning processing data of the multiple types of manufacturers; according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route; collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data serial connection; splicing the static link relations among a plurality of factories; judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set; according to the routing network communication protocol, the cross link is the link of different ports in the same network element, and the automatic audit of the serial data is carried out.

In one embodiment, the S100 includes:

s101: acquiring basic configuration data and basic client data of multiple manufacturers in a distributed manner, and summarizing the basic configuration data and the basic client data into multiple types of set data of the multiple manufacturers;

s102: various vendors include: a first type manufacturer, a second type manufacturer, a third type manufacturer and a fourth type manufacturer; the basic configuration data includes: network element configuration data, rack configuration data, machine frame configuration data, board configuration data, port configuration data, topology configuration data, cross configuration data, SNC configuration data, time slot configuration data and subnet configuration data;

s103: and carrying out unified analysis and classification and data cleaning processing on the multi-type set data of the multi-type manufacturer to obtain the cleaning processing data of the basic configuration of the multi-type manufacturer.

The working principle of the technical scheme is as follows: the S100 includes:

s101: acquiring basic configuration data and basic client data of multiple manufacturers in a distributed manner, and summarizing the basic configuration data and the basic client data into multiple types of set data of the multiple manufacturers;

s102: various types of manufacturers include: a first type manufacturer, a second type manufacturer, a third type manufacturer and a fourth type manufacturer; the basic configuration data includes: network element configuration data, rack configuration data, machine frame configuration data, board configuration data, port configuration data, topology configuration data, cross configuration data, SNC configuration data, time slot configuration data and subnet configuration data;

s103: and performing unified analysis and classification and data cleaning processing on the multi-type set data of the multiple types of manufacturers to obtain cleaning processing data of basic configuration of the multiple types of manufacturers.

The beneficial effects of the above technical scheme are: acquiring basic configuration data and basic client data of multiple manufacturers in a distributed manner, and summarizing the basic configuration data and the basic client data into multiple types of set data of the multiple manufacturers; various types of manufacturers include: a first type manufacturer, a second type manufacturer, a third type manufacturer and a fourth type manufacturer; the basic configuration data includes: network element configuration data, rack configuration data, machine frame configuration data, board configuration data, port configuration data, topology configuration data, cross configuration data, SNC configuration data, time slot configuration data and subnet configuration data; and performing unified analysis and classification and data cleaning processing on the multi-type set data of the multiple types of manufacturers to obtain cleaning processing data of basic configuration of the multiple types of manufacturers.

In one embodiment, the S200 includes:

s201: creating a transport network bearing relation combination; the transport network bearer relationship combination comprises: client layer routing, odu layer routing, otu layer routing, och layer routing and oms layer routing;

s202: combining the bearing relations of the transmission network, and sequentially bearing from a high order to a low order according to the bearing relations; the carrying from the high order to the low order according to the carrying relation comprises the following steps: sequentially carrying from an oms layer to an och layer to an otu layer to a client layer;

s203: carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route; the multistage transmission circuit includes: a client layer transmission circuit, an odu layer transmission circuit, an otu layer transmission circuit, an och layer transmission circuit and an oms layer transmission circuit.

The working principle of the technical scheme is as follows: the S200 includes:

s201: creating a transport network bearing relation combination; the transport network bearer relationship combination comprises: client layer routing, odu layer routing, otu layer routing, och layer routing and oms layer routing;

s202: combining the bearing relations of the transmission network, and sequentially bearing from a high order to a low order according to the bearing relations; the carrying from the high order to the low order according to the carrying relation comprises the following steps: sequentially carrying from an oms layer to an och layer to an otu layer to a client layer;

s203: splicing multi-layer routes of a multi-level transmission circuit through a basic multi-layer route; the multistage transmission circuit includes: a client layer transmission circuit, an odu layer transmission circuit, an otu layer transmission circuit, an och layer transmission circuit and an oms layer transmission circuit.

The beneficial effects of the above technical scheme are: creating a transport network bearing relation combination; the transport network bearer relationship combination comprises: client layer routing, odu layer routing, otu layer routing, och layer routing and oms layer routing; combining the bearing relations of the transmission network, and sequentially bearing from a high order to a low order according to the bearing relations; sequentially carrying from a high order to a low order according to a carrying relationship comprises the following steps: sequentially carrying from an oms layer to an och layer to an otu layer to a client layer; splicing multi-layer routes of a multi-level transmission circuit through a basic multi-layer route; the multistage transmission circuit includes: the device comprises a client layer transmission circuit, an odu layer transmission circuit, an otu layer transmission circuit, an och layer transmission circuit and an oms layer transmission circuit.

In one embodiment, the S300 includes:

s301: creating a plurality of segments of end-to-end routing data; the multi-segment end-to-end routing data includes: network element port data, topology data among network elements, network element internal cross data and inter-manufacturer static link resource data;

s302: carrying out end-to-end routing data concatenation on a plurality of sections of end-to-end routing data in a plurality of sections;

s303: and splicing the static link relations among a plurality of factories according to the multi-segment end-to-end routing data.

The working principle of the technical scheme is as follows: the S300 includes:

s301: creating a plurality of segments of end-to-end routing data; the multi-segment end-to-end routing data includes: network element port data, topology data among network elements, network element internal cross data and inter-manufacturer static link resource data;

s302: carrying out end-to-end routing data concatenation on a plurality of sections of end-to-end routing data in a plurality of sections;

s303: and splicing the static link relation among a plurality of factories according to the multi-section end-to-end routing data.

The beneficial effects of the above technical scheme are: creating a plurality of segments of end-to-end routing data; the multi-segment end-to-end routing data includes: network element port data, topology data among network elements, network element internal cross data and inter-manufacturer static link resource data; carrying out end-to-end routing data concatenation on a plurality of sections of end-to-end routing data in a plurality of sections; and splicing the static link relations among a plurality of factories according to the multi-segment end-to-end routing data.

In one embodiment, the S400 includes:

s401: setting an auxiliary operation method, screening algorithm input parameters, inputting the algorithm input parameters into an end-to-end route splicing algorithm of the transmission circuit for operation, and obtaining an end-to-end route splicing operation result of the transmission circuit;

s402: judging whether the current inquiry path type and the end-to-end route splicing are finished or not according to the end-to-end route splicing operation result of the transmission circuit, circularly splicing the route, and recursively inquiring whether the route path reaches an oms layer or not in sequence, wherein if the route path reaches the oms layer, the end-to-end route splicing is finished, and the result is collected into an end-to-end route set; obtaining an end-to-end route splicing state;

s403: and collecting an end-to-end route set through the transmission network according to the end-to-end route splicing state.

The working principle of the technical scheme is as follows: the S400 includes:

s401: setting an auxiliary operation method, screening algorithm input parameters, inputting the algorithm input parameters into an end-to-end route splicing algorithm of the transmission circuit for operation, and obtaining an end-to-end route splicing operation result of the transmission circuit;

s402: judging whether the current inquiry path type and the end-to-end route splicing are finished or not according to the end-to-end route splicing operation result of the transmission circuit, circularly splicing the route, and recursively inquiring whether the route path reaches an oms layer or not in sequence, wherein if the route path reaches the oms layer, the end-to-end route splicing is finished, and the result is collected into an end-to-end route set; obtaining an end-to-end route splicing state;

s403: and splicing the end-to-end routes, and collecting an end-to-end route set through a transmission network.

The beneficial effects of the above technical scheme are: setting an auxiliary operation method, screening algorithm input parameters, inputting the algorithm input parameters into an end-to-end route splicing algorithm of the transmission circuit for operation, and obtaining an end-to-end route splicing operation result of the transmission circuit; judging whether the current inquiry path type and the end-to-end route splicing are finished or not according to the end-to-end route splicing operation result of the transmission circuit, circularly splicing the route, and recursively inquiring whether the route path reaches an oms layer or not in sequence, wherein if the route path reaches the oms layer, the end-to-end route splicing is finished, and the result is collected into an end-to-end route set; obtaining an end-to-end route splicing state; and collecting an end-to-end route set through the transmission network according to the end-to-end route splicing state.

In one embodiment, the S500 includes:

s501: establishing a routing network communication protocol, and cross-linking the routing network communication protocol into links of different ports in the same network element;

s502: taking a plurality of manufacturers at any end as a starting point, and inquiring path search through the relationship among routing, topology, intersection and time slot to form an end-to-end complete path;

s503: and through an end-to-end complete path, the data feedback resources after the successful serial connection are used for production and use, and the automatic audit of the serial data is carried out.

The working principle of the technical scheme is as follows: the S500 includes:

s501: establishing a routing network communication protocol, and cross-linking the routing network communication protocol into links of different ports in the same network element;

s502: taking a plurality of factories at any end as a starting point, and inquiring path search through the relationship among routing, topology, intersection and time slot to form an end-to-end complete path;

s503: through an end-to-end complete path, data feedback resources after successful serial connection are used for production and use, and serial data automatic audit is carried out; and calculating the total transmission delay value of the end-to-end complete path, wherein the calculation formula is as follows:

DDYC represents the total transmission delay value of the end-to-end complete path, D represents the total number of types of data sent by a starting point, dpl represents the total number of manufacturer paths, D represents the number of types of data sent by the starting point, SFZ represents the number of types of data received by a routing end point, tpl represents the time from generation of a single type to reception of the routing end point, and ZFY represents the number of the end-to-end complete paths; the efficiency of the end-to-end complete path concatenation is further improved by calculating the total transmission delay value of the end-to-end complete path and reducing the delay.

The beneficial effects of the above technical scheme are: establishing a routing network communication protocol, and cross-linking the routing network communication protocol into links of different ports in the same network element; taking a plurality of manufacturers at any end as a starting point, and inquiring path search through the relationship among routing, topology, intersection and time slot to form an end-to-end complete path; through an end-to-end complete path, the data feedback resources after the serial connection is successful are used for production and use, and the serial data are automatically audited; calculating the total transmission delay value of the end-to-end complete path, wherein DDYC represents the total transmission delay value of the end-to-end complete path, D represents the total number of data types sent by a starting point, dpl represents the total number of manufacturer paths, D represents the number of types of data sent by the starting point, SFZ represents the number of types of data received by a routing end point, tpl represents the time from generation of a single type to reception of the single type by the routing end point, and ZFY represents the number of the end-to-end complete paths; the efficiency of the end-to-end complete path concatenation is further improved by calculating the total transmission delay value of the end-to-end complete path and reducing the delay; the accuracy of production and use is greatly improved.

In one embodiment, the S103 includes:

s1031, performing unified analysis and classification on the multi-type set data of the various manufacturers; the unified analysis and classification comprises the following steps: classifying the classified data into multi-type classified data; the multi-type classification data includes: point type data, line type data, and net type data;

s1032, the dot type data includes: the system comprises a network element, a frame, a machine frame, a board card, a port and a time slot; the line type data includes: topology, crossover, SNC and SNC routing; the net type data includes: subnet type data and client data;

and S1033, obtaining cleaning processing data of the basic configuration of the various manufacturers through data cleaning processing.

The working principle of the technical scheme is as follows: the S103 includes:

s1031, performing unified analysis and classification on multi-type set data of multiple types of manufacturers; the unified analysis and classification comprises the following steps: classifying the classified data into multi-type classified data; the multi-type classification data includes: point type data, line type data, and net type data; the step of integrally classifying the classified data into the multi-type classified data comprises the following steps: arranging a plurality of types of set data information of a plurality of types of manufacturers into a structural data whole, learning through a pre-association structure according to a manufacturer data set and an information database to obtain the co-appearing association relationship of each type of set data, constructing a pre-association network structure, aggregating front and back ordered set data belonging to the same type in the pre-association network to obtain corresponding set data classification, forming a corresponding strategy scheme according to an expert experience knowledge map to output an analysis result to a user, searching an optimal solution by adopting an ant colony algorithm, adopting an early pruning minimum association rule set during classification, and removing irrelevant classification rules; obtaining multi-type classification data;

s1032, the dot type data includes: the system comprises a network element, a frame, a machine frame, a board card, a port and a time slot; the line type data includes: topology, crossover, SNC and SNC routing; the net type data includes: subnet type data and customer data;

and S1033, obtaining cleaning processing data of the basic configuration of the various manufacturers through data cleaning processing.

The beneficial effects of the above technical scheme are: carrying out unified analysis and classification on multi-type set data of multiple types of manufacturers; the unified analysis and classification comprises the following steps: classifying the classified data into multi-type classified data; the multi-type classification data includes: point type data, line type data, and net type data; the step of integrally classifying the classified data into the multi-type classified data comprises the following steps: arranging a plurality of types of set data information of a plurality of types of manufacturers into a structural data whole, learning through a pre-association structure according to a manufacturer data set and an information database to obtain the co-appearing association relationship of each type of set data, constructing a pre-association network structure, aggregating front and back ordered set data belonging to the same type in the pre-association network to obtain corresponding set data classification, forming a corresponding strategy scheme according to an expert experience knowledge map to output an analysis result to a user, searching an optimal solution by adopting an ant colony algorithm, adopting an early pruning minimum association rule set during classification, and removing irrelevant classification rules; obtaining multi-type classification data; the point type data includes: the system comprises a network element, a frame, a machine frame, a board card, a port and a time slot; the line type data includes: topology, crossover, SNC and SNC routing; the net type data includes: subnet type data and client data; and cleaning data of the basic configuration of various manufacturers are obtained through data cleaning.

In one embodiment, the S203 includes:

s2031, establishing a basic multilayer route; defining each layer of route starting point and each layer of route end point of the basic multilayer route;

and S2032, taking the route end point of each layer as the starting point of the previous layer of route, and splicing the multi-layer routes of the multi-stage transmission circuit.

The working principle of the technical scheme is as follows: the S203 includes:

s2031, establishing a basic multilayer route; defining each layer of route starting point and each layer of route end point of the basic multilayer route;

s2032, taking the route end point of each layer as the starting point of the previous layer of route, and carrying out multi-layer route splicing of the multi-stage transmission circuit; the multilevel transmission circuit multilayer routing splicing comprises the following steps: determining each root node of the multi-prefix tree; allocating different initial point/route end point network communication node pairs to different prefix trees, and enabling the different initial point/route end point network communication node pairs to transmit data through different prefix trees; intelligently self-updating a local dynamic routing table through a cloud dynamic routing table matching strategy, keeping the priority order of a local static routing table, searching an optimal routing transmission path and a suboptimal transmission path, and splicing the transmission of a single transmission path into multi-layer routing transmission; transmitting data from each layer of route starting point to each layer of route end point; and carrying out multi-layer routing splicing on the multi-stage transmission circuit.

The beneficial effects of the above technical scheme are: establishing a basic multi-layer route; defining each layer of route starting point and each layer of route end point of the basic multilayer route; taking the route end points of all layers as the starting points of the routes of the previous layer, and splicing the multi-layer routes of the multi-stage transmission circuit; the multilevel transmission circuit multilayer routing splicing comprises the following steps: determining each root node of the multi-prefix tree; allocating different initial point/route end point network communication node pairs to different prefix trees, and enabling the different initial point/route end point network communication node pairs to transmit data through different prefix trees; intelligently self-updating a local dynamic routing table through a cloud dynamic routing table matching strategy, keeping the priority order of a local static routing table, searching an optimal routing transmission path and a suboptimal transmission path, and splicing the transmission of a single transmission path into multi-layer routing transmission; transmitting data from each layer of route starting point to each layer of route end point; and carrying out multi-layer route splicing of a multi-stage transmission circuit.

In one embodiment, the S503 includes:

s5031, through an end-to-end complete path, an end-to-end complete path content set is combined through crossing and topology, and two crossing ends do not span a network element;

s5032, intelligently and automatically judging whether the end-to-end path serial connection is successful; when the two ends do not meet the cross and do not span the network element, the end-to-end path fails to be connected in series, and the intelligent cycle adjustment is fed back; when the two ends of the intersection are not crossed by the network element, the end-to-end path is successfully connected in series;

s5033, when the end-to-end path is successfully connected in series, the data feedback resource after successful connection is used for production, and automatic audit of the data in series is performed.

The working principle of the technical scheme is as follows: the S503 includes:

s5031, through an end-to-end complete path, an end-to-end complete path content set crosses and is topologically combined, and both ends of the cross do not cross network elements;

s5032, intelligently and automatically judging whether the end-to-end path concatenation is successful; when the two ends do not meet the cross and do not span the network element, the end-to-end path fails to be connected in series, and the intelligent cycle adjustment is fed back; when the two ends of the path accord with the cross and do not cross the network element, the end-to-end path is successfully connected in series;

s5033, when the end-to-end path is successfully connected in series, the data feedback resource after successful connection is used for production, and automatic audit of the data in series is performed.

The beneficial effects of the above technical scheme are: through an end-to-end complete path, an end-to-end complete path content set is combined through crossing and topology, and two crossed ends do not cross network elements; intelligently and automatically judging whether the end-to-end path concatenation is successful or not; when the two ends do not meet the cross and the network element is not crossed, the end-to-end path fails to be connected in series, and the intelligent cycle adjustment is carried out through feedback; when the two ends of the intersection are not crossed by the network element, the end-to-end path is successfully connected in series; when the end-to-end path is successfully connected in series, the data feedback resources after the end-to-end path is successfully connected in series are used for production and use, and automatic audit of the data in series is carried out.

The invention provides a transmission network service circuit route automatic series connection and data checking system, comprising:

the system adopts the transmission network service circuit route automatic serial connection and data checking method.

The working principle of the technical scheme is as follows: the transmission network service circuit route automatic concatenation and data check system includes:

the system adopts the transmission network service circuit route automatic serial connection and data checking method.

The beneficial effects of the above technical scheme are: the transmission network service circuit route automatic concatenation and data check system includes: a system adopting the transmission network service circuit route automatic serial connection and data checking method; collecting multi-type set data of multiple manufacturers in a distributed manner, carrying out unified analysis and classification and data cleaning processing, and obtaining basic configuration cleaning processing data of the multiple manufacturers; according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route; collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data concatenation; splicing the static link relations among a plurality of factories; judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set; according to the routing network communication protocol, the cross link is the link of different ports in the same network element, and the automatic audit of the serial data is carried out.

While embodiments of the invention have been disclosed above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims (10)

1. The method for automatically connecting the transmission network service circuit routes in series and checking the data is characterized by comprising the following steps:

s100: collecting multi-type set data of multiple manufacturers in a distributed manner, carrying out unified analysis and classification and data cleaning processing, and obtaining basic configuration cleaning processing data of the multiple manufacturers;

s200: according to the combination of the bearing relation of the transmission network, carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route;

s300: collecting basic configuration cleaning processing data of various manufacturers to carry out multi-section end-to-end routing data concatenation; splicing the static link relations among a plurality of manufacturers;

s400: judging whether the current query path type and the end-to-end route splicing are finished or not through an end-to-end route splicing algorithm of a transmission circuit, and collecting an end-to-end route set;

s500: according to the routing network communication protocol, the cross link is the link of different ports in the same network element, and the automatic audit of the serial data is carried out.

2. The method for transmission network service circuit route automatic concatenation and data check according to claim 1, wherein said S100 comprises:

s101: acquiring basic configuration data and basic client data of multiple manufacturers in a distributed manner, and summarizing the basic configuration data and the basic client data into multiple types of set data of the multiple manufacturers;

s102: various vendors include: a first type manufacturer, a second type manufacturer, a third type manufacturer and a fourth type manufacturer; the basic configuration data includes: network element configuration data, rack configuration data, machine frame configuration data, board configuration data, port configuration data, topology configuration data, cross configuration data, SNC configuration data, time slot configuration data and subnet configuration data;

s103: and carrying out unified analysis and classification and data cleaning processing on the multi-type set data of the multi-type manufacturer to obtain the cleaning processing data of the basic configuration of the multi-type manufacturer.

3. The method for transmission network service circuit route automatic concatenation and data check according to claim 1, wherein said S200 comprises:

s201: creating a transport network bearing relation combination; the transport network bearer relationship combination comprises: client layer routing, odu layer routing, otu layer routing, och layer routing and oms layer routing;

s202: combining the bearing relations of the transmission network, and sequentially bearing from a high order to a low order according to the bearing relations; the carrying from the high order to the low order according to the carrying relation comprises the following steps: sequentially carrying from an oms layer to an och layer to an otu layer to a client layer;

s203: carrying out multi-layer route splicing of a multi-level transmission circuit through a basic multi-layer route; the multistage transmission circuit includes: a client layer transmission circuit, an odu layer transmission circuit, an otu layer transmission circuit, an och layer transmission circuit and an oms layer transmission circuit.

4. The method for transmission network service circuit route automatic concatenation and data check according to claim 1, wherein said S300 comprises:

s301: creating a plurality of segments of end-to-end routing data; the multi-segment end-to-end routing data includes: network element port data, topology data among network elements, network element internal cross data and inter-manufacturer static link resource data;

s302: the multi-segment end-to-end routing data is divided into a plurality of segments to carry out end-to-end routing data serial connection;

s303: and splicing the static link relations among a plurality of factories according to the multi-segment end-to-end routing data.

5. The method for transmission network service circuit route automatic concatenation and data check according to claim 1, wherein said S400 comprises:

s401: setting an auxiliary operation method, screening algorithm input parameters, inputting the parameters into an end-to-end route splicing algorithm of the transmission circuit for operation, and obtaining an end-to-end route splicing operation result of the transmission circuit;

s402: judging whether the type of the current query path and the splicing of the end-to-end route are finished or not according to the splicing operation result of the end-to-end route of the transmission circuit, circularly splicing the route, sequentially and recursively querying whether the route path reaches an oms layer or not, finishing the splicing of the end-to-end route if the route path reaches the oms layer, and collecting the result into an end-to-end route set; obtaining an end-to-end route splicing state;

s403: and collecting an end-to-end route set through the transmission network according to the end-to-end route splicing state.

6. The method for transmission network service circuit route automatic concatenation and data check according to claim 1, wherein said S500 comprises:

s501: establishing a routing network communication protocol, and cross-linking the routing network communication protocol into links of different ports in the same network element;

s502: taking a plurality of manufacturers at any end as a starting point, and inquiring path search through the relationship among routing, topology, intersection and time slot to form an end-to-end complete path;

s503: and through an end-to-end complete path, the data feedback resources after the successful serial connection are used for production and use, and the automatic audit of the serial data is carried out.

7. The method for transport network service circuit route automatic concatenation and data checking according to claim 2, wherein said S103 comprises:

s1031, performing unified analysis and classification on the multi-type set data of the various manufacturers; the unified analysis and classification comprises the following steps: classifying the classified data into multi-type classified data; the multi-type classification data includes: point type data, line type data, and net type data;

s1032, the dot type data includes: the system comprises network elements, a frame, a machine frame, a board card, a port and a time slot; the line type data includes: topology, crossover, SNC and SNC routing; the net type data includes: subnet type data and client data;

and S1033, obtaining cleaning processing data of the basic configuration of the various manufacturers through data cleaning processing.

8. The method for transport network service circuit route automatic concatenation and data checking according to claim 3, wherein said S203 comprises:

s2031, establishing a basic multilayer route; defining each layer of route starting point and each layer of route end point of the basic multilayer route;

and S2032, taking the route end point of each layer as the starting point of the previous layer of route, and splicing the multi-layer routes of the multi-stage transmission circuit.

9. The method for transmission network service circuit route automatic concatenation and data check according to claim 6, wherein said S503 comprises:

s5031, through an end-to-end complete path, an end-to-end complete path content set is combined through crossing and topology, and two crossing ends do not span a network element;

s5032, intelligently and automatically judging whether the end-to-end path concatenation is successful; when the two ends do not meet the cross and do not span the network element, the end-to-end path fails to be connected in series, and the intelligent cycle adjustment is fed back; when the two ends of the intersection are not crossed by the network element, the end-to-end path is successfully connected in series;

s5033, when the end-to-end path is successfully connected in series, the data feedback resource after successful connection is used for production, and automatic audit of the data in series is performed.

10. The transmission network service circuit route automatic concatenation and data check system characterized by, includes:

a system for employing the method for automatic concatenation of traffic circuit routes and data verification for a transmission network according to any one of claims 1 to 9.

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