CN116545864A

CN116545864A - Data processing method and platform suitable for optical cable line management system

Info

Publication number: CN116545864A
Application number: CN202310819773.1A
Authority: CN
Inventors: 臧伟; 肖杨明; 宗丽英; 汪雨翔; 徐国华; 马爱军; 张国平; 吴云鹏; 虞思城; 张云峰; 杨佳彬
Original assignee: Zhejiang Tailun Power Group Co ltd Power Transmission Engineering Branch; Huzhou Power Supply Co of State Grid Zhejiang Electric Power Co Ltd
Current assignee: Zhejiang Tailun Power Group Co ltd Power Transmission Engineering Branch; Huzhou Power Supply Co of State Grid Zhejiang Electric Power Co Ltd
Priority date: 2023-07-06
Filing date: 2023-07-06
Publication date: 2023-08-04
Anticipated expiration: 2043-07-06
Also published as: CN116545864B

Abstract

The invention provides a data processing method and a data processing platform suitable for an optical cable line management system, which are used for generating a corresponding first optical cable line connection diagram according to first optical cable line configuration data, judging that a user selects a first optical transmission node and inputs corresponding second optical cable line configuration data, and generating a second optical transmission node parallel to the first optical transmission node; generating optical cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, and carrying out combined display on the corresponding first optical transmission nodes and second optical transmission nodes in the first optical cable line connection diagram based on the optical cable layer information to obtain a second optical cable line connection diagram; corresponding patrol identities are distributed to patrol identity codes corresponding to the first optical transmission node and the second optical transmission node to obtain a corresponding patrol list; and outputting the inspection display result corresponding to the second optical cable line connection diagram after the result output requirement is met.

Description

Data processing method and platform suitable for optical cable line management system

Technical Field

The present invention relates to data processing technologies, and in particular, to a data processing method and a platform suitable for an optical cable line management system.

Background

The optical cable line management system is a management system specially developed for the optical cable line management of the industry. At present, the influence of optical cable faults on the telecommunication industry is large, and the faults of optical cable lines can cause large-area station breakage to bring adverse effects on the satisfaction degree and society of operators, so that the guarantee of the normal operation of the optical cable lines is very important.

In the prior art, optical signals are mainly transmitted through optical cable lines and optical signal transmission equipment in the transmission process, corresponding optical cable line diagrams are generated according to the optical cable lines and the optical signal transmission equipment to carry out inspection, but in practical application, the requirements of different places are different, the requirements of part of signal transmission places are larger, and corresponding transmission equipment for transmitting optical signals is more, however, the prior art cannot embody that the practical quantity of the optical signal transmission equipment leads to poor inspection effect and the corresponding optical cable line diagrams are not visual enough.

Therefore, how to construct a relatively visual optical cable line graph according to actual conditions so as to assist staff in formulating a reasonable inspection strategy becomes a problem to be solved urgently.

Disclosure of Invention

The embodiment of the invention provides a data processing method and a data processing platform suitable for an optical cable line management system, which can construct a relatively visual optical cable line graph according to actual conditions so as to ensure that subsequent patrol allocation is relatively reasonable.

In a first aspect of an embodiment of the present invention, a data processing method applicable to an optical cable line management system is provided, including:

the optical cable line management system generates a corresponding first optical cable line connection diagram according to first optical cable line configuration data of a user, wherein the first optical cable line connection diagram at least comprises first optical transmission nodes corresponding to first optical transmission equipment and first optical cables connected between the first optical transmission nodes;

if the fact that the user selects the first optical transmission node and inputs corresponding second optical cable line configuration data is judged, generating a second optical transmission node parallel to the first optical transmission node according to the second optical cable line configuration data;

generating corresponding optical cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, and carrying out combined display on the corresponding first optical transmission nodes and the corresponding second optical transmission nodes in the first optical cable line connection diagram based on the optical cable layer information to obtain a second optical cable line connection diagram;

the optical cable line management system divides a second optical cable line connection diagram according to the routing inspection information input by a user, generates a routing inspection section corresponding to each routing inspection identity code in the routing inspection information, and distributes corresponding routing inspection identities to the routing inspection identity codes corresponding to the first optical transmission node and the second optical transmission node to obtain a corresponding routing inspection list;

The optical cable line management system interacts with the inspection terminal of the inspection personnel, and displays corresponding first optical transmission nodes and second optical transmission nodes in the second optical cable line connection diagram in a corresponding display mode according to the interaction result, and outputs an inspection display result corresponding to the second optical cable line connection diagram after the result output requirement is met.

Optionally, in one possible implementation manner of the first aspect, the optical cable line management system generates a corresponding first optical cable line connection diagram according to first optical cable line configuration data of a user, where the first optical cable line connection diagram includes at least a first optical transmission node corresponding to the first optical transmission device, and a first optical cable connected between the first optical transmission nodes, and the method includes:

the optical cable line management system determines a geographic information diagram corresponding to the optical cable setting area, and determines corresponding first optical transmission nodes in the geographic information diagram according to node position information in the first optical cable line configuration data, wherein each first optical transmission node has a corresponding first node code;

connecting a plurality of first optical transmission nodes according to connection relation information among the plurality of first optical transmission nodes in the first optical cable line configuration data to obtain a first optical cable line connection diagram, wherein the connection relation information is provided with node codes of the connected first optical transmission nodes;

And encoding the first optical cable between all the connected first optical transmission nodes in the first optical cable line connection diagram to obtain corresponding cable codes.

Optionally, in one possible implementation manner of the first aspect, if it is determined that the user selects the first optical transmission node and inputs corresponding second optical cable line configuration data, generating, according to the second optical cable line configuration data, a second optical transmission node parallel to the first optical transmission node includes:

if the user selects the first optical transmission node and inputs corresponding second optical cable line configuration data, the corresponding first optical transmission node is used as the first optical transmission node to be adjusted, and the number of the second optical transmission nodes configured by the second optical cable line configuration data is obtained;

modifying a first optical transmission node to be adjusted into a preset relay summary node, and generating corresponding parallel connecting lines according to the relay summary node serving as a starting point;

and vertically connecting the corresponding first optical transmission node and the corresponding second optical transmission node with parallel connecting wires with preset lengths, and coding the corresponding second optical transmission node to obtain a second node code.

Optionally, in one possible implementation manner of the first aspect, the vertically connecting the corresponding first optical transmission node and the second optical transmission node with a first parallel connection line with a preset length, and encoding the corresponding second optical transmission node to obtain a second node code includes:

Obtaining the sum of the node numbers according to the numbers of the first optical transmission nodes and the second optical transmission nodes, and equally dividing first parallel connection lines with a first preset length based on the sum of the node numbers if the sum of the node numbers is less than or equal to the preset node number, so as to obtain a plurality of first equal-division nodes;

the first optical transmission node and the second optical transmission node are respectively connected with a first equal-division node through a first sub optical cable, and the first sub optical cable is perpendicular to the first parallel connection line;

if the sum of the node numbers is judged to be larger than the preset node number, equally dividing a second parallel connecting line with a second preset length based on the sum of the node numbers to obtain a plurality of second equally divided nodes;

and the first optical transmission node and the second optical transmission node are respectively connected with a second halving node through a second sub optical cable, the second sub optical cable is perpendicular to the second parallel connecting line, and the first optical transmission node, the second sub optical cable and the second parallel connecting line are folded and displayed.

Optionally, in one possible implementation manner of the first aspect, the connecting the first optical transmission node and the second optical transmission node with the second aliquoting node through second sub optical cables, where the second sub optical cable is perpendicular to the second parallel connection line, and folding and displaying the first optical transmission node, the second sub optical cable, and the second parallel connection line includes:

The first optical transmission node and the second optical transmission node are respectively connected with a second aliquoting node and an edge point through a second sub optical cable to obtain unfolding display structures of the first optical transmission node and the second optical transmission node;

generating a preset folding parallel connecting line, and halving the folding parallel connecting line to obtain folding halving nodes of the folding parallel connecting line;

connecting the first optical transmission node with folding equal nodes of the folding parallel connecting line through a second sub optical cable, and connecting the second optical transmission node with edge points of the folding parallel connecting line through the second sub optical cable;

and determining the central point of the area formed by the folding parallel connection line and the two second sub-optical cables, generating unfolding additive images according to the number of the first optical transmission nodes and the second optical transmission nodes, and setting the unfolding additive images at the central point.

Optionally, in one possible implementation manner of the first aspect, the determining a center point of an area formed by the folded parallel connection line and the two second sub-optical cables, generating an expansion adding image according to the number of the first optical transmission nodes and the second optical transmission nodes, and setting the expansion adding image at the center point includes:

Acquiring first node coordinates and second node coordinates of a first optical transmission node and a second optical transmission node corresponding to the coordinated first optical cable line connection diagram, and acquiring a Y-axis center point according to the Y-axis coordinates of the first node coordinates and the second node coordinates;

obtaining the coordinate of an aliquoting node of the folded aliquoting node after the coordinate processing, obtaining an X-axis center point according to the first node coordinate and the X-axis coordinate of the aliquoting node coordinate, and determining the center point of the formed area according to the X-axis center point and the Y-axis center point;

generating unfolding adding images according to the number of the first optical transmission nodes and the second optical transmission nodes, and acquiring the center point of the unfolding adding images and the center point of the formed area to be overlapped.

Optionally, in one possible implementation manner of the first aspect, the generating the expansion adding image according to the number of the first optical transmission node and the second optical transmission node, and acquiring a center point of the expansion adding image and a center point of the formed area are overlapped, including:

determining the number of display points in the unfolded and added image according to the number of the first optical transmission nodes and the number of the second optical transmission nodes, wherein the number of the first optical transmission nodes and the number of the second optical transmission nodes have a preset corresponding relation with the number of the display points in the image;

Uniformly setting the number display points in the corresponding number of images at intervals to obtain expanded added images, wherein the number display points in different numbers of images have different preset intervals;

and configuring corresponding trigger response conditions for the expansion adding image, and controlling the first optical transmission node, the second sub-optical cable and the second parallel connecting line to expand the display structure for display after the expansion adding image is triggered.

Optionally, in one possible implementation manner of the first aspect, the method further includes:

when judging that the time for displaying the first optical transmission node, the second sub-optical cable and the second parallel connecting line by unfolding the display structure is greater than or equal to the first preset time, folding and displaying the first optical transmission node, the second sub-optical cable and the second parallel connecting line.

Optionally, in one possible implementation manner of the first aspect, the generating corresponding optical cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, and displaying the corresponding first optical transmission nodes and the corresponding second optical transmission nodes in the first optical cable line connection diagram in a combined manner based on the optical cable layer information to obtain the second optical cable line connection diagram includes:

Generating corresponding optical cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, wherein the optical cable layer information comprises layer numbers corresponding to the first optical transmission nodes and the second optical transmission nodes respectively;

and adding corresponding layer numbers to each first optical transmission node and each second optical transmission node to obtain a second optical cable line connection diagram.

Optionally, in one possible implementation manner of the first aspect, the optical cable line management system segments the second optical cable line connection diagram according to the routing inspection information input by the user, generates a routing inspection segment corresponding to each routing inspection identity code in the routing inspection information, and obtains a corresponding routing inspection list for routing inspection identities corresponding to routing inspection identity codes corresponding to the first optical transmission node and the second optical transmission node, where the routing inspection list includes:

obtaining the average inspection length of each inspection person according to the number of the inspection persons, the length of the first optical cable and the length of the second optical cable in the inspection information, wherein the second optical cable comprises a first sub optical cable or a second sub optical cable;

dividing the second optical cable circuit connection diagram according to the number of the patrol personnel and the average patrol length to obtain a patrol section corresponding to each patrol identity;

And acquiring a first node code and a second node code corresponding to each first optical transmission node and each second optical transmission node in the inspection section, and acquiring an inspection list according to the inspection sections where the first optical transmission node and the second optical transmission node are located and corresponding inspection identities corresponding to the corresponding first node code and the second node code.

Optionally, in one possible implementation manner of the first aspect, the dividing the second optical cable line connection diagram according to the average routing length according to the number of the routing inspection personnel to obtain the routing inspection segment corresponding to each routing inspection identity includes:

randomly selecting any one patrol identity, and sequentially selecting corresponding first optical cables according to the connection relation of all the first optical transmission nodes in the second optical cable line connection diagram and the corresponding first optical transmission nodes in the second optical cable line connection diagram as starting points;

if the selected first optical transmission node is judged to have a parallel second optical transmission node, corresponding distribution inspection lengths are obtained according to the lengths of the first optical cable and the second optical cable respectively connected with the first optical transmission node and the second optical transmission node;

when the distributed routing inspection length is larger than or equal to the average routing inspection length, the selected lines formed by the first optical transmission node, the second optical transmission node, the first optical cable and the second optical cable are used as routing inspection sections corresponding to the corresponding routing inspection identities.

Optionally, in one possible implementation manner of the first aspect, the optical cable line management system interacts with an inspection terminal of an inspector, and displays corresponding first optical transmission nodes and second optical transmission nodes in the second optical cable line connection diagram in a corresponding display manner according to an interaction result, and outputs an inspection display result corresponding to the second optical cable line connection diagram after reaching a result output requirement, where the method includes:

when the patrol personnel carry out patrol, the patrol identity codes of the corresponding first optical transmission node and the second optical transmission node are identified based on the patrol terminal and sent to the optical cable line management system;

the optical cable line management system displays a first optical transmission node and a second optical transmission node corresponding to the received inspection identity in a first display mode on a second optical cable line connection diagram;

after judging that all the first optical transmission nodes and the second optical transmission nodes are displayed in a first display mode respectively, judging that the data requirements are met and outputting inspection display results corresponding to the second optical cable line connection diagram.

In a second aspect of an embodiment of the present invention, there is provided a data processing platform adapted for use in a cable line management system, including:

The system comprises a generation module, a first optical cable line management system and a first optical cable management system, wherein the generation module is used for enabling the optical cable line management system to generate a corresponding first optical cable line connection diagram according to first optical cable line configuration data of a user, and the first optical cable line connection diagram at least comprises first optical transmission nodes corresponding to first optical transmission equipment and first optical cables connected between the first optical transmission nodes;

the judging module is used for generating a second optical transmission node parallel to the first optical transmission node according to the second optical cable line configuration data if judging that a user selects the first optical transmission node and inputs the corresponding second optical cable line configuration data;

the display module is used for generating corresponding optical cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, and carrying out combined display on the corresponding first optical transmission nodes and the corresponding second optical transmission nodes in the first optical cable line connection diagram based on the optical cable layer information to obtain a second optical cable line connection diagram;

the separation module is used for dividing the second optical cable circuit connection diagram according to the routing inspection information input by a user by the optical cable circuit management system, generating a routing inspection section corresponding to each routing inspection identity code in the routing inspection information, and distributing corresponding routing inspection identities to the routing inspection identity codes corresponding to the first optical transmission node and the second optical transmission node to obtain a corresponding routing inspection list;

And the output module is used for enabling the optical cable line management system to interact with the inspection terminal of the inspection personnel, displaying the corresponding first optical transmission node and the corresponding second optical transmission node in the second optical cable line connection diagram in a corresponding display mode according to the interaction result, and outputting the inspection display result corresponding to the second optical cable line connection diagram after the result output requirement is met.

In a third aspect of embodiments of the present invention, there is provided a storage medium having stored therein a computer program for implementing the method of the first aspect and the various possible designs of the first aspect when the computer program is executed by a processor.

The beneficial effects of the invention are as follows:

1. according to the invention, a more visual second optical cable line connection diagram is constructed according to the actual condition of the optical cable line, and the second optical cable line connection diagram is utilized for routing inspection distribution, so that the routing inspection of the corresponding second optical transmission node is avoided, and the subsequent routing inspection effect is better. The invention constructs the corresponding parallel second optical transmission node according to the actual condition of each first optical transmission node in each first optical cable line connection diagram, and combines and displays the second optical transmission node and the first optical transmission node, thereby obtaining a second optical cable line connection diagram corresponding to the actual condition, and displaying the signal transmission structure of each place in the actual application; according to the invention, the second optical cable line connection diagram is divided and allocated, so that each routing inspection identity corresponds to a corresponding routing inspection section, each transmission node cannot be subjected to routing inspection neglected, and the fault probability is reduced.

2. According to the invention, the first optical transmission nodes and the second optical transmission nodes are displayed in different forms (folded or unfolded) according to the number of the preset relay aggregation nodes in the second optical cable line connection diagram, and the layer numbers of the corresponding transmission nodes are displayed, so that a user can observe more intuitively, more transmission nodes and fewer transmission nodes can be seen from the second optical cable line connection diagram intuitively. The invention generates a corresponding first optical cable line connection diagram according to the first optical cable line configuration data and the geographic information diagram, determines a relay summary node in the first optical cable line connection diagram, equally divides the first parallel connection line according to the sum of the node numbers at the relay summary node to obtain a plurality of first equally divided nodes, thereby connecting the first optical transmission node and the second optical transmission node with the second equally divided node through the second sub optical cable respectively and displaying the first optical transmission node and the second optical transmission node, and at the moment, the observation is more visual, the number of the optical transmission nodes corresponding to each place can be known, and the actual connection condition of the optical signal transmission corresponding to each place can be directly displayed through the layered structure of the optical transmission nodes; in consideration of the situation that the mess is caused by too many nodes, the invention adopts 2 modes for displaying, when the number of the sum of the number of the nodes is smaller than or equal to the preset number of the nodes, the nodes are directly connected and displayed in an unfolding mode, and when the number of the sum of the number of the nodes is larger than the preset number of the nodes, the nodes are connected through folding parallel connecting lines and displayed in a folding mode.

3. When the unfolding adding image is generated, the corresponding unfolding adding image is added to the central point of the folding area, the number of the display points in the unfolding adding image has a preset corresponding relation with the number of the first optical transmission nodes and the second optical transmission nodes, the number of the display points in the unfolding adding image is larger corresponding to the larger number of the first optical transmission nodes and the second optical transmission nodes, and the distances between the different display points are different, so that the display interface is simpler. And after the user triggers the added image, the first optical transmission node, the second sub optical cable and the second parallel connecting line are displayed in an unfolding display structure, so that the user can observe conveniently, more points of the transmission node can be intuitively displayed, and the user can automatically fold the added image after triggering, so that the whole display is more concise and convenient for the user to observe.

4. According to the invention, the patrol section of the patrol personnel is distributed according to the second optical cable line connection diagram, so that each optical cable line can be patrol, and the average distribution is carried out, so that the workload of each patrol personnel is moderate. The invention can carry out inspection distribution by using the second optical cable line connection diagram, so that each optical transmission node and the corresponding sub optical cable can be inspected subsequently, thereby reducing the failure rate, interacting with the inspection terminal of the inspection personnel after the inspection is finished, displaying the inspected nodes in a first display mode, indicating the inspection is finished, and facilitating the observation and the direct positioning of the problematic area by a subsequent manager.

Drawings

FIG. 1 is a flow chart of a data processing method suitable for use in a fiber optic cable line management system;

fig. 2 is a schematic diagram of a relay summary node;

FIG. 3 is a schematic diagram of an expanded display of an optical transmission node;

FIG. 4 is a schematic diagram of a folded display of an optical transmission node;

fig. 5 is a schematic diagram of a data processing platform suitable for use in a cable management system.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms "first," "second," "third," "fourth" and the like in the description and in the claims and in the above drawings, if any, are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the invention described herein may be implemented in sequences other than those illustrated or otherwise described herein.

It should be understood that, in various embodiments of the present invention, the sequence number of each process does not mean that the execution sequence of each process should be determined by its functions and internal logic, and should not constitute any limitation on the implementation process of the embodiments of the present invention.

It should be understood that in the present invention, "comprising" and "having" and any variations thereof are intended to cover non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements that are expressly listed or inherent to such process, method, article, or apparatus.

It should be understood that in the present invention, "plurality" means two or more. "and/or" is merely an association relationship describing an association object, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. The character "/" generally indicates that the context-dependent object is an "or" relationship. "comprising A, B and C", "comprising A, B, C" means that all three of A, B, C comprise, "comprising A, B or C" means that one of the three comprises A, B, C, and "comprising A, B and/or C" means that any 1 or any 2 or 3 of the three comprises A, B, C.

It should be understood that in the present invention, "B corresponding to a", "a corresponding to B", or "B corresponding to a" means that B is associated with a, from which B can be determined. Determining B from a does not mean determining B from a alone, but may also determine B from a and/or other information. The matching of A and B is that the similarity of A and B is larger than or equal to a preset threshold value.

As used herein, "if" may be interpreted as "at … …" or "at … …" or "in response to a determination" or "in response to detection" depending on the context.

The technical scheme of the invention is described in detail below by specific examples. The following embodiments may be combined with each other, and some embodiments may not be repeated for the same or similar concepts or processes.

The invention provides a data processing method suitable for an optical cable line management system, as shown in fig. 1, comprising the following steps of S1-S4:

s1, the optical cable line management system generates a corresponding first optical cable line connection diagram according to first optical cable line configuration data of a user, wherein the first optical cable line connection diagram at least comprises first optical transmission nodes corresponding to first optical transmission equipment and first optical cables connected between the first optical transmission nodes.

The first optical transmission node is an equipment node for transmitting an optical signal, for example, may be an optical transmission device such as an optical transceiver.

It may be appreciated that, before performing optical cable line management, a corresponding first optical cable line connection diagram is generated according to the first optical cable line configuration data, where the first optical cable line connection diagram shows a connection relationship between each first optical transmission node in the area, and the connected lines are first optical cables.

Through the embodiment, the first optical cable line connection diagram among all the sites in the area can be generated, and the corresponding second optical transmission node can be conveniently constructed based on the first optical cable line connection diagram.

In some embodiments, the step S1 (the cable line management system generates a corresponding first cable line connection diagram according to the first cable line configuration data of the user, where the first cable line connection diagram includes at least a first optical transmission node corresponding to the first optical transmission device and a first optical cable connected between the first optical transmission nodes), includes S11-S14:

s11, the optical cable line management system determines a geographic information diagram corresponding to the optical cable setting area, and determines corresponding first optical transmission nodes in the geographic information diagram according to node position information in the first optical cable line configuration data, wherein each first optical transmission node has a corresponding first node code.

It can be understood that, firstly, a geographical information diagram corresponding to the optical cable setting area is obtained, and according to the node position information in the first optical cable line configuration data, a corresponding geographical position is determined on the geographical information diagram as the first optical transmission node.

The node location information is geographical location information where the first optical transmission node is located, and the node location information may be location information of an office building or may be location information of a cell, which is not limited herein.

Wherein each first optical transmission node has a corresponding first node code, e.g., node A, B, etc., without limitation.

And S12, connecting the plurality of first optical transmission nodes according to the connection relation information among the plurality of first optical transmission nodes in the first optical cable line configuration data to obtain a first optical cable line connection diagram, wherein the connection relation information has node codes of the connected first optical transmission nodes.

It should be noted that, the first optical cable line configuration data includes a connection relationship between the first optical transmission nodes, for example, the connection relationship between the first optical transmission nodes may be displayed by the first node code, and the node a and the node B are connected, which is not limited herein.

It can be understood that, according to the connection relationship between the plurality of first optical transmission nodes, the first optical transmission nodes are connected to obtain a first optical cable line connection diagram.

It is to be understood that the place where the first optical transmission node is located may be a place such as an office building, and the office building has a high requirement, so that a plurality of optical transmission nodes exist.

S13, coding the first optical cable lines among all the connected first optical transmission nodes in the first optical cable line connection diagram to obtain corresponding cable codes.

It can be understood that after the first optical cable line connection diagram is obtained, the connection line between the first optical transmission nodes is a first optical cable, and the first optical cable is encoded to obtain a cable code. For example, the first optical cable may be encoded by a first node code of two first optical transmission nodes, for example, node a and node B are connected, and a cable code of the first optical cable between the two is AB, which is not limited herein.

S2, if the first optical transmission node is selected by the user and corresponding second optical cable line configuration data is input, generating a second optical transmission node parallel to the first optical transmission node according to the second optical cable line configuration data.

It should be noted that, the requirements of different sites are different, and the corresponding numbers of transmission devices for transmitting optical signals are different, so that there may be a plurality of optical terminals at one site.

It can be understood that if it is determined that the user selects the first optical transmission node and inputs the corresponding second optical cable line configuration data, it is indicated that there are a plurality of optical transmission devices at the first optical transmission node, and therefore, a second optical transmission node parallel to the first optical transmission node is generated according to the second optical cable line configuration data, where the second optical transmission node is a device node that transmits an optical signal in parallel to the first optical transmission node.

For example, each floor of a 3-floor office building has a corresponding optical transceiver, 1 optical transceiver for floor 1, 1 optical transceiver for floor 2, and 1 optical transceiver for floor 3.

In some embodiments, in step S2 (if it is determined that the user selects the first optical transmission node and inputs the corresponding second optical cable line configuration data, a second optical transmission node parallel to the first optical transmission node is generated according to the second optical cable line configuration data), including S21-S23:

S21, if the user selects the first optical transmission node and inputs corresponding second optical cable line configuration data, the corresponding first optical transmission node is used as the first optical transmission node to be adjusted, and the number of the second optical transmission nodes configured by the second optical cable line configuration data is obtained.

It can be understood that if the user selects the first optical transmission node and inputs the corresponding second optical cable line configuration data, the corresponding first optical transmission node is used as the first optical transmission node to be adjusted, so that subsequent adjustment is facilitated, and the number of second optical transmission nodes at the first optical transmission node is acquired.

For example, each layer of the 3-layer office building has a corresponding optical transceiver, and the first optical transmission nodes correspond to the layer 1 of the office building, and then the number of the second optical transmission nodes is 2.

S22, modifying the first optical transmission node to be adjusted into a preset relay summary node, and generating corresponding parallel connecting lines according to the relay summary node serving as a starting point.

The relay summary node is a first optical transmission node with a parallel second optical transmission node.

It should be noted that, when there are a plurality of optical transmission nodes at the first optical transmission node to be adjusted, at this time, the first optical cable line connection diagram cannot intuitively show the number of the corresponding optical transmission nodes.

Therefore, as shown in fig. 2, the first optical transmission node to be adjusted is modified into a preset relay summary node, and a parallel connection line is generated by taking the relay summary node as a starting point, so that the connection and display of the parallel connection lines of the plurality of optical transmission nodes and the relay summary node are convenient.

S23, corresponding first optical transmission nodes and second optical transmission nodes are vertically connected with parallel connecting lines with preset lengths, and the corresponding second optical transmission nodes are coded to obtain second node codes.

It can be understood that after the first optical transmission node and the second optical transmission node are vertically connected with the parallel connection lines with the corresponding preset lengths, the corresponding relay summary nodes can be used for displaying the number of the optical transmission nodes owned by the place, so that a user can intuitively observe the corresponding optical transmission nodes.

It will be appreciated that, in the same principle as the first optical transmission node code, the present invention also encodes the second optical transmission node to obtain the second node code.

In some embodiments, in step S23 (the corresponding first optical transmission node, the corresponding second optical transmission node are vertically connected to the first parallel connection line with the preset length, and the second node code is obtained by encoding the corresponding second optical transmission node), including S231-S234:

S231, obtaining the sum of the node numbers according to the numbers of the first optical transmission nodes and the second optical transmission nodes, and equally dividing the first parallel connection lines with the first preset length based on the sum of the node numbers if the sum of the node numbers is less than or equal to the preset number of the nodes, so as to obtain a plurality of first equal-divided nodes.

Wherein the sum of the number of nodes is the sum of the number of first optical transmission nodes and the number of second optical transmission nodes.

For example, when the office building is 30 floors and the network demand is large, the number of the first optical transmission nodes and the second optical transmission nodes is large, and at this time, the display is performed directly, which results in excessively complicated pictures and inconvenient observation.

Therefore, the invention counts the number of the first optical transmission nodes and the second optical transmission nodes to obtain the sum of the number of the nodes, and if the number of the sum of the number of the nodes is less than or equal to the preset number of the nodes, the first parallel connection lines with the first preset length are equally divided according to the sum of the number of the nodes to obtain a plurality of first equally divided nodes.

For example, the preset number of nodes may be 3, which is not limited herein. For example, the number of the sums of the number of the nodes is 3, and at this time, the number of the sums of the number of the nodes is equal to the preset number of the nodes, and then 3 equal division processing is performed on the first parallel connection lines with the first preset length according to 3, so as to obtain 3 first equal division nodes.

S232, the first optical transmission node and the second optical transmission node are respectively connected with the first equal-division node through a first sub optical cable, and the first sub optical cable is perpendicular to the first parallel connection line.

It can be understood that the present invention generates a first sub-optical cable perpendicular to the first parallel connection line, and connects the first optical transmission node and the second optical transmission node with the first equal-division node through the first sub-optical cable respectively.

For example, as shown in fig. 3, one end of each of the 3 first sub-optical cables is connected to a first equal-dividing node, and the other end of each of the first sub-optical cables is connected to a first optical transmission node and a second optical transmission node, and the display is directly unfolded.

Through the embodiment, the invention can directly develop and display the first optical transmission node and the second optical transmission node with smaller number.

S233, if the sum of the node numbers is larger than the preset node number, equally dividing the second parallel connection lines with the second preset length based on the sum of the node numbers to obtain a plurality of second equally divided nodes.

It can be understood that if the number of the sums of the number of the nodes is greater than the preset number of the nodes, the same principle as that of step S231 is adopted, and the second parallel connection lines with the second preset length are equally divided based on the sum of the number of the nodes, so as to obtain a plurality of second equally divided nodes. It will be appreciated that the nodes remain equally divided by the sum of the number of nodes, except that they are subsequently presented in the form of a collapsed display. Wherein the second preset length is greater than the first preset length.

For example, the preset number of nodes may be 3, which is not limited herein. For example, the number of the sums of the number of the nodes is 6, and at this time, the number of the sums of the number of the nodes is greater than the preset number of the nodes, and then 6 equal division processing is performed on the first parallel connection lines with the first preset length according to 6, so as to obtain 6 second equal division nodes.

And S234, the first optical transmission node and the second optical transmission node are respectively connected with a second halving node through a second sub optical cable, the second sub optical cable is perpendicular to the second parallel connecting line, and the first optical transmission node, the second sub optical cable and the second parallel connecting line are folded and displayed.

It can be understood that the second sub-optical cable perpendicular to the second parallel connection line is generated, and the first optical transmission node and the second optical transmission node are respectively connected with the second halving node through the second sub-optical cable, so that the display state is in the unfolded display state, and the display of the optical transmission nodes is more due to the fact that the display of the optical transmission nodes is more, so that the observation by a user is inconvenient.

Therefore, the first optical transmission node, the second sub optical cable and the second parallel connecting line are folded and displayed, and the optical transmission node of the middle part of the unfolded and displayed is folded, so that the user can observe conveniently.

In some embodiments, in step S234 (the first optical transmission node, the second optical transmission node are connected to the second halving node through the second sub-optical cables, the second sub-optical cable is perpendicular to the second parallel connection line, and the first optical transmission node, the second sub-optical cables and the second parallel connection line are folded and displayed), S2341-S2344 are included:

s2341, the first optical transmission node and the second optical transmission node are respectively connected with the second aliquoting node and the edge point through the second sub optical cable to obtain the unfolding display structure of the first optical transmission node and the second optical transmission node.

After the second parallel connection lines are equally divided according to the number of the first optical transmission nodes and the second optical transmission nodes, the second equally divided nodes are respectively located at the second parallel connection lines and at edge points of the second parallel connection lines.

Therefore, the first optical transmission node and the second optical transmission node are connected with the second aliquoting node and the edge point through the second sub optical cable, so that the unfolding display structure of the first optical transmission node and the second optical transmission node in the unfolded state is obtained.

S2342, a preset folding parallel connecting line is generated, and the folding parallel connecting line is halved to obtain folding halving nodes of the folding parallel connecting line.

In this case, since the number of the first optical transmission nodes and the second optical transmission nodes is large, a predetermined folded parallel connection line is generated, and the length of the folded parallel connection line is smaller than the second predetermined length. And halving the folding parallel connecting lines to obtain folding halving nodes of the folding parallel connecting lines, wherein the folding halving nodes are respectively positioned at the middle position and the edge point of the folding parallel connecting lines.

S2343, connecting the first optical transmission node with the folding equal node of the folding parallel connection line through the second sub optical cable, and connecting the second optical transmission node with the edge point of the folding parallel connection line through the second sub optical cable.

It can be understood that at this time, 2 second sub-optical cables are generated and connected perpendicularly to the folded equal-dividing nodes, the first optical transmission node is connected to the folded equal-dividing node at the middle position of the folded parallel connection line, and the second optical transmission node is connected to the edge point of the folded parallel connection line through the second sub-optical cables.

S2344, determining the center point of the area formed by the folding parallel connection line and the two second sub-optical cables, generating unfolding additive images according to the number of the first optical transmission nodes and the second optical transmission nodes, and setting the unfolding additive images at the center point.

The number of the first optical transmission nodes and the second optical transmission nodes is large, and folding display is performed here, but after the folding parallel connection lines are generated and the like, only 2 optical transmission nodes are displayed, and a plurality of the optical transmission nodes cannot be represented.

Thus, the server determines the center point of the area formed by the folded parallel connection line and the two second sub-optical cables. It can be understood that the above-mentioned area is a rectangular area, and after the parallel connection line is folded to form a type area with two second sub-optical cables, the end point of one end of the type opening is connected to obtain a closed area, so as to determine the center point of the area.

And generating unfolding adding images according to the number of the first optical transmission nodes and the second optical transmission nodes, wherein the unfolding adding images are images with ellipses preset in advance manually, determining the center point of the unfolding adding images at the moment, and setting the centers of the images and the center points of the areas to be corresponding to each other.

For example, as shown in fig. 4, the number of the sums of the node numbers is 6, at this time, the number of the sums of the node numbers is greater than the preset number of the nodes, halving processing is performed on the folded parallel connection lines to obtain 2 folded halved nodes, the 2 folded halved nodes are respectively connected with the first optical transmission node and the second optical transmission node, and an unfolding added image is arranged in the center of a type area.

In some embodiments, in step S2344 (determining the center point of the area formed by the folded parallel connection line and the two second sub-optical cables, generating an unfolded additive image according to the number of the first optical transmission nodes and the second optical transmission nodes, and setting the unfolded additive image at the center point) includes:

and acquiring first node coordinates and second node coordinates of the first optical transmission node and the second optical transmission node corresponding to the coordinated first optical cable line connection diagram, and acquiring a Y-axis center point according to the Y-axis coordinates of the first node coordinates and the second node coordinates.

It can be understood that the present invention coordinates the first optical cable line connection diagram, and may be that any point in the first optical cable line connection diagram is selected to establish a coordinate system for the coordinate processing.

Therefore, the coordinates of the central points of the first optical transmission node and the second optical transmission node corresponding to the first optical cable line connection diagram can be obtained, wherein the first optical transmission node and the second optical transmission node are all round nodes.

It is to be understood that the Y-axis coordinate value of the center point of the area, that is, the Y-axis center point, is obtained from the average of the Y-axis coordinates and the values of the first node coordinates and the second node coordinates according to the Y-coordinate value of the center point of the area formed by the folded parallel connection line and the two second sub-optical cables.

And obtaining the coordinate of the aliquoting node of the folded aliquoting node after the coordinate processing, obtaining an X-axis center point according to the first node coordinate and the X-axis coordinate of the aliquoting node coordinate, and determining the center point of the formed area according to the X-axis center point and the Y-axis center point.

It can be understood that the server may obtain the coordinates of the bisector nodes in the middle position of the folded bisector nodes, and obtain the X-axis coordinate value of the center point of the area, that is, the X-axis center point, according to the average value of the X-axis coordinates and the values of the first node coordinates and the coordinates of the bisector nodes.

Thus, the center point of the formed region is determined from the X-axis center point and the Y-axis center point of the region center.

It can be understood that the expansion adding image is generated according to the number of the first optical transmission nodes and the second optical transmission nodes, the more the number of the first optical transmission nodes and the second optical transmission nodes is, the more corresponding expansion adding images are in ellipses, at this time, the center point of the expansion adding image is obtained, and the center point of the expansion adding image and the center point of the formed area are overlapped, so that a folding display mode is obtained.

In some embodiments, the step of generating a spread add image according to the number of the first optical transmission node and the second optical transmission node, and acquiring a setting that a center point of the spread add image overlaps a center point of the formed area includes:

and determining the number of the display points of the number in the unfolded and added image according to the number of the first optical transmission nodes and the number of the second optical transmission nodes, wherein the number of the first optical transmission nodes and the number of the second optical transmission nodes and the number of the display points of the number in the image have a preset corresponding relation.

It can be understood that when the number of the first optical transmission nodes and the second optical transmission nodes is larger, the number of the display points in the expanded addition image is larger, and when the number of the first optical transmission nodes and the second optical transmission nodes is smaller, the number of the display points in the expanded addition image is smaller. The number of the first optical transmission nodes and the second optical transmission nodes has a preset corresponding relation with the number of the display points in the image.

For example, when the number of the first optical transmission nodes and the second optical transmission nodes is 6 to 12, the number of the display points in the image is 2, when the number of the first optical transmission nodes and the second optical transmission nodes is 12 to 18, the number of the display points in the image is 4, and when the number of the first optical transmission nodes and the second optical transmission nodes is 18 or more, the number of the display points in the image is 6.

Through the embodiment, after the folding display is performed, the picture is simpler when a user observes, meanwhile, the user can directly determine whether the number of the first optical transmission nodes and the second optical transmission nodes at the position is more or not through the number of the display points in the image, and can trigger the unfolding and adding image to display in an unfolding mode subsequently, so that the number of the optical transmission nodes and the corresponding layers of the optical transmission nodes can be directly determined.

And uniformly setting the number display points in the corresponding number of images at intervals to obtain expanded added images, wherein the number display points in different numbers of images have different preset intervals.

It can be understood that the size of the unfolding additive image is consistent, and the number of the display points in the image is different, the number of the display points in the unfolding additive image can be uniformly arranged at intervals, and it is easy to understand that the interval distance of 3 points is larger than the interval distance of 6 points, so that the image of the unfolding additive image is simpler, and the user can observe the image conveniently.

In the case of a place with many optical transmission nodes, the optical transmission node to be displayed in the expanded state is displayed in a folded state.

Therefore, the server configures a corresponding trigger response condition for the expansion adding image, and when the expansion adding image is triggered, the server controls the first optical transmission node, the second sub-optical cable and the second parallel connection line to expand the display structure for display.

According to the embodiment, the display is performed in the folded mode under the condition that the unfolding and adding image is not triggered, and after the triggering is performed by a user, the display is performed in the unfolded mode, so that the number of the optical transmission nodes is displayed in detail, the display interface is concise, and meanwhile, the user can directly obtain the corresponding number of the optical transmission nodes from the image.

On the basis of the above embodiment, the method further comprises:

It can be understood that, after each time of expanding the additional image is triggered, the first preset time is displayed under the expanded display structure by the first optical transmission node, the second sub-optical cable and the second parallel connection line, and when the display time is greater than or equal to the first preset time, the folded display is restored to the first optical transmission node, the second sub-optical cable and the second parallel connection line.

And S3, generating corresponding optical cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, and carrying out combined display on the corresponding first optical transmission nodes and the corresponding second optical transmission nodes in the first optical cable line connection diagram based on the optical cable layer information to obtain a second optical cable line connection diagram.

In practical application, the first optical transmission node and the second optical transmission node respectively correspond to corresponding optical cable layer information, for example, 3 layers of office buildings, the optical transceiver a corresponds to 1 layer, the optical transceiver B corresponds to 2 layers, and the optical transceiver C corresponds to 3 layers.

Therefore, corresponding optical cable layer information is set for each first optical transmission node and each second optical transmission node, and combined connection display is carried out at the corresponding relay summary node, so that a second optical cable line connection diagram is obtained.

In some embodiments, in step S3 (generating corresponding cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, and displaying the corresponding first optical transmission nodes and the second optical transmission nodes in the first cable line connection diagram in a combined manner based on the cable layer information to obtain the second cable line connection diagram) includes S31-S32:

s31, corresponding optical cable layer information is generated according to the number of the first optical transmission nodes and the second optical transmission nodes, and the optical cable layer information comprises layer numbers corresponding to the first optical transmission nodes and the second optical transmission nodes respectively.

It can be understood that the optical cable layer information includes layer numbers corresponding to the first optical transmission node and the second optical transmission node respectively, for example, 3 layers of office buildings, the optical transceiver a corresponds to 1 layer, the optical transceiver B corresponds to 2 layers, and the optical transceiver C corresponds to 3 layers.

And S32, adding corresponding layer numbers to each first optical transmission node and each second optical transmission node to obtain a second optical cable line connection diagram.

It can be understood that the server adds the layer number corresponding to the geographical position point for each optical transmission node, and performs combined display on the first optical transmission node and the second optical transmission node to obtain a second optical cable line connection diagram.

And S4, the optical cable line management system divides the second optical cable line connection diagram according to the routing inspection information input by the user, generates a routing inspection section corresponding to each routing inspection identity code in the routing inspection information, and distributes corresponding routing inspection identities to the routing inspection identity codes corresponding to the first optical transmission node and the second optical transmission node to obtain a corresponding routing inspection list.

It can be understood that the optical cable line management system segments the length of the optical cable line in the second optical cable line connection diagram according to the inspection information input by the user, for example, the number of people to be inspected, so as to generate an inspection segment corresponding to each inspection identity in the inspection information.

It is easy to understand that the first optical transmission node and the second optical transmission node exist in the corresponding inspection section, each optical transmission node has a corresponding node code and a layer number, so that the inspection identity code of each inspection personnel has the node codes of the corresponding first optical transmission node and the second optical transmission node, and an inspection list is obtained.

In some embodiments, step S4 (the optical cable line management system divides the second optical cable line connection diagram according to the routing inspection information input by the user, generates a routing inspection segment corresponding to each routing inspection identity code in the routing inspection information, and allocates corresponding routing inspection identities to the routing inspection identities corresponding to the first optical transmission node and the second optical transmission node to obtain a corresponding routing inspection list), includes S41-S43:

S41, obtaining the average inspection length of each inspection personnel according to the number of the inspection personnel, the length of the first optical cable and the length of the second optical cable in the inspection information, wherein the second optical cable comprises the first sub optical cable or the second sub optical cable.

It can be understood that the server can perform average processing according to the number of the patrol personnel in the patrol information and the length of the first optical cable line and the length of the second optical cable line in the second optical cable line connection diagram, so as to obtain an average patrol length of each patrol personnel, for example, the patrol total length is 10 meters, and if 10 patrol personnel, each personnel patrol 1 meter.

S42, dividing the second optical cable circuit connection diagram according to the number of the patrol personnel and the average patrol length to obtain a patrol section corresponding to each patrol identity.

It can be understood that the second optical cable line connection graph is segmented based on the average routing inspection length, and the routing inspection segments corresponding to each routing inspection identity can be obtained by sequentially traversing the lengths from the starting point to the end point for segmentation.

In some embodiments, in step S42 (dividing the second optical cable line connection diagram according to the average routing inspection length according to the number of the routing inspection personnel to obtain the routing inspection segment corresponding to each routing inspection identity), the method includes S421-S423:

S421, randomly selecting any one patrol identity, and sequentially selecting corresponding first optical cables according to the connection relation of all the first optical transmission nodes in the second optical cable line connection diagram and the corresponding first optical transmission nodes in the second optical cable line connection diagram as starting points.

It will be appreciated that the server will traverse the length of the cable in the second cable routing graph a little by little in the form of a traversed length, distributing the patrol personnel.

Therefore, the server randomly selects any one inspection identity, and sequentially traverses the lengths of the optical cable lines according to the corresponding first optical transmission nodes in the second optical cable line as the starting points and the connection sequence between the first optical transmission nodes, so as to obtain corresponding first optical cables, and it is easy to understand that the first optical transmission nodes from the starting points to the end points of optical signal transmission can be sequentially traversed, so that the corresponding inspection sections can be conveniently obtained subsequently.

S422, if the selected first optical transmission node has the parallel second optical transmission node, the corresponding distribution inspection length is obtained according to the lengths of the first optical cable and the second optical cable respectively connected with the first optical transmission node and the second optical transmission node.

It can be understood that if the selected first optical transmission node is judged to have the parallel second optical transmission node, at this time, the first optical transmission node and the parallel second optical transmission node are connected through the second optical cable, and when the length is traversed, the lengths of the first optical cable and the second optical cable respectively connected with the first optical transmission node and the second optical transmission node are traversed to obtain corresponding distributed inspection lengths.

S423, when judging that the distributed routing inspection length is greater than or equal to the average routing inspection length, taking the selected lines formed by the first optical transmission node, the second optical transmission node, the first optical cable and the second optical cable as routing inspection sections corresponding to the corresponding routing inspection identities.

It can be understood that when the traversed distribution routing inspection length is greater than or equal to the average routing inspection length, the traversed first optical transmission node, the traversed second optical transmission node, the traversed first optical cable and the traversed second optical cable form a routing inspection section corresponding to the corresponding routing inspection identity.

S43, acquiring a first node code and a second node code corresponding to each first optical transmission node and each second optical transmission node in the inspection section, and acquiring an inspection list according to the inspection sections where the first optical transmission node and the second optical transmission node are located and corresponding inspection identities corresponding to the corresponding first node code and the second node code.

It can be understood that each first optical transmission node and each second optical transmission node have corresponding node codes, each inspection personnel has corresponding inspection identities, and the node codes of the first optical transmission node and the second optical transmission node corresponding to the inspection section of each inspection personnel correspond to the corresponding inspection identity codes, so as to obtain an inspection list corresponding to the inspection personnel.

And S5, the optical cable line management system interacts with the inspection terminal of the inspection personnel, and displays corresponding first optical transmission nodes and second optical transmission nodes in the second optical cable line connection diagram in a corresponding display mode according to the interaction result, and outputs an inspection display result corresponding to the second optical cable line connection diagram after the result output requirement is met.

It is easy to understand that when the inspection personnel completes inspection, the inspection terminal is operated, for example, the inspection two-dimensional code at the corresponding first optical transmission node and the second optical transmission node is scanned, the inspection is completed, and at this time, the first optical transmission node and the second optical transmission node are displayed in a corresponding display mode, for example, the first optical transmission node and the second optical transmission node are switched from blue to green.

Therefore, when all the nodes in the second optical cable line connection diagram are displayed with the colors after inspection, the inspection is finished, and the inspection display result corresponding to the second optical cable line connection diagram is output.

In some embodiments, in step S5 (where the optical cable line management system interacts with the inspection terminal of the inspector, and displays the corresponding first optical transmission node and the corresponding second optical transmission node in the second optical cable line connection diagram in a corresponding display manner according to the interaction result), after the result output requirement is met, the inspection display result corresponding to the second optical cable line connection diagram is output, including S51-S53:

s51, when the patrol personnel carry out patrol, the patrol identity codes of the corresponding first optical transmission node and the second optical transmission node are identified based on the patrol terminal and sent to the optical cable line management system.

It should be noted that, the first optical transmission node and the second optical transmission node both have corresponding routing inspection identity codes.

Therefore, when the patrol personnel carry out patrol, the patrol identity codes of the corresponding first optical transmission node and the second optical transmission node can be identified based on the patrol terminal and sent to the optical cable line management system, and the patrol is represented to finish.

S52, the optical cable line management system displays a first optical transmission node and a second optical transmission node corresponding to the received inspection identity in a first display mode on a second optical cable line connection diagram.

It can be understood that the optical cable line management system may receive the inspection identity code identified by the inspection terminal, and display the corresponding first optical transmission node and the corresponding second optical transmission node on the second optical cable line connection diagram in a first display manner, for example, the first optical transmission node and the second optical transmission node are adjusted from blue to green to display, which represents that the inspection is completed.

Through the embodiment, an administrator can directly judge the areas after inspection and the areas without inspection through the colors, so that the method is more visual.

And S53, after judging that all the first optical transmission nodes and the second optical transmission nodes are respectively displayed in the first display mode, judging that the data requirements are met and outputting a patrol display result corresponding to the second optical cable line connection diagram.

It can be understood that when all the first optical transmission nodes and the second optical transmission nodes are displayed in the first display mode, and all the lines and the optical transmission nodes are inspected, the inspection display result corresponding to the second optical cable line connection diagram is output.

In order to better implement the data processing method suitable for the optical cable line management system provided by the present invention, the present invention further provides a data processing platform suitable for the optical cable line management system, as shown in fig. 5, including:

The present invention also provides a storage medium having stored therein a computer program for implementing the methods provided by the various embodiments described above when executed by a processor.

The storage medium may be a computer storage medium or a communication medium. Communication media includes any medium that facilitates transfer of a computer program from one place to another. Computer storage media can be any available media that can be accessed by a general purpose or special purpose computer. For example, a storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. The processor and the storage medium may reside in an application specific integrated circuit (Application Specific Integrated Circuits, ASIC for short). In addition, the ASIC may reside in a user device. The processor and the storage medium may reside as discrete components in a communication device. The storage medium may be read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tape, floppy disk, optical data storage device, etc.

The present invention also provides a program product comprising execution instructions stored in a storage medium. The at least one processor of the device may read the execution instructions from the storage medium, the execution instructions being executed by the at least one processor to cause the device to implement the methods provided by the various embodiments described above.

In the above embodiments of the terminal or the server, it should be understood that the processor may be a central processing unit (english: central Processing Unit, abbreviated as CPU), or may be other general purpose processors, digital signal processors (english: digital Signal Processor, abbreviated as DSP), application specific integrated circuits (english: application Specific Integrated Circuit, abbreviated as ASIC), or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of a method disclosed in connection with the present invention may be embodied directly in a hardware processor for execution, or in a combination of hardware and software modules in a processor for execution.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims

1. A data processing method suitable for use in an optical cable line management system, comprising:

2. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 1,

the optical cable line management system generates a corresponding first optical cable line connection diagram according to first optical cable line configuration data of a user, wherein the first optical cable line connection diagram at least comprises first optical transmission nodes corresponding to first optical transmission equipment, and first optical cables for connecting the first optical transmission nodes, and the optical cable line management system comprises:

3. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 2,

if the user selects the first optical transmission node and inputs the corresponding second optical cable line configuration data, generating a second optical transmission node parallel to the first optical transmission node according to the second optical cable line configuration data, including:

4. A data processing method suitable for use in a fiber optic cable line management system as claimed in claim 3,

the corresponding first optical transmission node and second optical transmission node are vertically connected with a first parallel connection line with a preset length, and the corresponding second optical transmission node is encoded to obtain a second node code, which comprises the following steps:

5. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 4,

the first optical transmission node and the second optical transmission node are respectively connected with a second halving node through a second sub optical cable, the second sub optical cable is perpendicular to the second parallel connecting line, and the first optical transmission node, the second sub optical cable and the second parallel connecting line are folded and displayed, and the method comprises the following steps:

6. The method for data processing for a fiber optic cable line management system of claim 5,

the determining the center point of the area formed by the folded parallel connection line and the two second sub-optical cables, generating an unfolding adding image according to the number of the first optical transmission nodes and the second optical transmission nodes, and setting the unfolding adding image at the center point comprises the following steps:

7. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 6,

Generating an unfolding adding image according to the number of the first optical transmission nodes and the second optical transmission nodes, and acquiring the overlapping setting of the central point of the unfolding adding image and the central point of the formed area comprises the following steps:

8. The data processing method for a fiber optic cable line management system of claim 7, further comprising:

9. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 8,

generating corresponding optical cable layer information according to the number of the first optical transmission nodes and the second optical transmission nodes, and carrying out combined display on the corresponding first optical transmission nodes and the corresponding second optical transmission nodes in the first optical cable line connection diagram based on the optical cable layer information to obtain a second optical cable line connection diagram, wherein the method comprises the following steps:

10. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 9,

the optical cable line management system segments a second optical cable line connection diagram according to routing inspection information input by a user, generates routing inspection sections corresponding to each routing inspection identity code in the routing inspection information, distributes corresponding routing inspection identities to the routing inspection identity codes corresponding to the first optical transmission node and the second optical transmission node to obtain a corresponding routing inspection list, and comprises the following steps:

11. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 10,

the second optical cable line connection diagram is divided according to the number of the patrol personnel and the average patrol length to obtain patrol segments corresponding to each patrol identity, and the method comprises the following steps:

12. The method for data processing suitable for use in a fiber optic cable line management system as set forth in claim 11,

the optical cable line management system interacts with a patrol terminal of a patrol personnel, and displays corresponding first optical transmission nodes and second optical transmission nodes in a second optical cable line connection diagram in a corresponding display mode according to interaction results, and outputs patrol display results corresponding to the second optical cable line connection diagram after reaching result output requirements, and the system comprises:

13. Data processing platform suitable for optical cable line management system, characterized by comprising: