WO2020098553A1

WO2020098553A1 - Optical fiber network node management method and system

Info

Publication number: WO2020098553A1
Application number: PCT/CN2019/116118
Authority: WO
Inventors: 高�浩; 周鸣; 陈天奇
Original assignee: 烽火通信科技股份有限公司
Priority date: 2018-11-14
Filing date: 2019-11-07
Publication date: 2020-05-22
Also published as: CN109618250A; CN109618250B

Abstract

An optical fiber network node management method and system, related to the field of optical fiber network communication. The method comprises: providing an electronic label for each optical fiber network node, and associating an ID of the electronic label with all attribute information of a corresponding optical fiber network node; a background server performing classification according to the various facilities in which the optical fiber network nodes are located as indicated in the associated information and, for each category, sorting and establishing a model according to a specific position; a mobile smart terminal reading the electronic label ID and then querying the background server, and receiving returned data; and displaying by means of the model the specific position of the corresponding optical fiber network node in the facility thereof, the model comprising a link to all of the attribute information of the corresponding optical fiber network node. The present invention quickly and accurately locates a specified optical fiber network node, reduces memory space requirements for the electronic label, and improves the efficiency of deployment and maintenance of an entire optical fiber network.

Description

Optical fiber network node management method and system

Technical field

The present invention relates to the field of optical fiber network communications, and in particular to a method and system for optical fiber network node management.

Background technique

In the traditional optical fiber network management system, the optical fiber port and the box are all passive nodes. The management method of the optical fiber and the box is mainly marked by manual paper labels. This management method is not only inefficient, but the information is prone to error and loss. With the continuous development of the Internet of Things technology and big data, there is an urgent need for an efficient, platform-based management method for optical fiber network nodes.

For the management of optical fiber network nodes, many manufacturers have proposed their own solutions, some of which use RFID (Radio Frequency Identification) technology, that is, collecting information on electronic tags through RFID collectors, and uploading the collected data to the back-end server storage. The premise of this method is to set electronic tags on each component that needs to be managed, and write at least one attribute content for each electronic tag. This not only requires the electronic tag to have a writeable memory space, but also Before the maintenance of components, the electronic label needs to be rewritten to reduce the efficiency of deployment and maintenance of the entire optical fiber network.

In addition, the data uploaded to the background server is stored in the form of an isolated database, and the front-end collection device calls the data stored in the background server and presents it to the user in text. In this way, in a fiber-optic network node-intensive scenario, the location of the specified fiber-optic network node cannot be quickly and accurately located. At the same time, when the data of the fiber-optic network node is very large, node search and association search will be quite time-consuming.

Summary of the invention

In view of the defects in the prior art, the object of the present invention is to provide a fiber network node management method and system to quickly and accurately locate the designated fiber network node location, reduce the need for electronic tag memory space, and improve the deployment and maintenance of the entire fiber network s efficiency.

In order to achieve the above purpose, on the one hand, the technical solution adopted is a fiber network node management method, including steps:

Each optical network node is provided with an electronic label, and the electronic label ID is associated with all attribute information of the corresponding optical network node;

The background server is classified according to the different facilities where the fiber network nodes in the associated information are located, and sorted and modeled in each category according to the specific location;

After reading the electronic tag ID, the mobile intelligent terminal queries the back-end server and receives the returned data, and displays the specific location in the facility where the corresponding optical fiber network node is located through the model, and the model includes links to all attribute information of the corresponding optical fiber network node.

Preferably, the associated information received by the background server includes: the electronic tag ID read by the mobile intelligent terminal, and all attribute information of the corresponding optical fiber network node input through the mobile intelligent terminal.

Preferably, the attribute information includes a specific location and multiple attributes, and each attribute includes multiple individuals; the background server generates a virtual fiber network node according to each associated information; the multiple virtual fiber network nodes are classified as the same individual In the first category, a fiber optic network cluster is generated.

Preferably, the attributes of the attribute information further include fiber type, operator, plugging and unplugging status and age, the background server is classified according to the same individual and generates a fiber network cluster, and multiple virtual fiber networks in the same fiber network cluster Nodes are sorted and modeled in a preset order, or directly modeled without order.

Preferably, when the attribute is a facility, each facility is an individual, and in the background server, all virtual fiber network nodes in the same fiber network cluster perform distributed ranking modeling according to specific locations.

Preferably, after the mobile smart terminal reads the electronic tag ID and queries the backend server and receives the returned data, the mobile smart terminal specifically sends a query request carrying the electronic tag ID to the backend server, and the backend server searches for the corresponding virtual fiber network node according to The optical fiber network cluster classified by the facility, and returns the model data of the corresponding virtual optical network node in the optical fiber network cluster to the mobile intelligent terminal.

Preferably, the mobile intelligent terminal receives the data returned by the background server and displays the model, wherein the specific positions of all virtual fiber network nodes correspond to the specific positions of actual fiber network nodes.

Preferably, when the mobile intelligent terminal displays the model of the optical fiber network cluster, the virtual optical fiber network node corresponding to the read electronic tag ID is highlighted, and the virtual optical fiber network node links all its attribute information, and all the attribute information is displayed through a separate interface.

Preferably, the attribute information further includes specific locations of other fiber network nodes associated with the corresponding fiber network node; the background server establishes corresponding fiber network nodes and associated fibers according to the specific locations of the other fiber network nodes Map channels between network nodes, and establish an associated model of the fiber network cluster where the virtual fiber network nodes at both ends of the map channel are located, and assign a channel number to each mapped channel.

Preferably, in the model displayed by the mobile intelligent terminal, the virtual fiber network node corresponding to the read electronic tag ID is highlighted, and the virtual fiber network node displays all of its attribute information through a separate interface or displays The association model, and the mapping channel is displayed in the association model.

Preferably, when there is more than one correlation model, the corresponding virtual model is selected and displayed by the associated virtual fiber network node, and the opposite virtual fiber network node in the correlation model links all its attribute information.

Preferably, when the mobile intelligent terminal displays all attribute information of the virtual optical fiber network node, if the attribute information is modified, the mobile intelligent terminal reports the modified attribute information to the backend server, and the backend server controls the virtuality according to the modified attribute information. The optical nodes are reclassified, and the model of the fiber network cluster where the reclassification is located is modified.

Preferably, when the mobile intelligent terminal displays the model of the optical fiber network cluster, if the specific location modification information of the highlighted virtual optical fiber node is received, the mobile intelligent terminal reports the specific location modification information and the electronic tag ID to the backend server, and the backend server Modify the information and electronic tag ID according to the specific location, reclassify the virtual optical node and rebuild the model.

Preferably, the optical fiber network node includes a port, an optical fiber cable, a box, and a connector used in the optical fiber network; the electronic label plane is attached to the optical fiber network node, or embedded in the optical fiber network node.

On the other hand, adopt a kind of optical fiber network node management system, including:

Multiple electronic tags, each with a unique ID and installed on a fiber optic network node;

Information interaction module, which is installed in the mobile intelligent terminal, is used to read the electronic tag ID and communicate with the user and the background server;

The management service module, which is set in the background server, is used to receive the electronic tag ID and all attribute information of the corresponding optical fiber network node sent by the information interaction module, classify according to different facilities where the optical fiber network node is located, and according to the specific location Ranking modeling in each category;

The display module, which is set in the mobile intelligent terminal, is used to display the specific position and all attributes of the corresponding optical fiber network node in the model.

Preferably, the management service module includes:

Transceiver module, which is used to receive the electronic tag ID sent by the information interaction module and the attribute information of the corresponding optical fiber network node; also used to send the established model data to the information interaction module;

A modeling module, which is used to generate a virtual optical fiber network node based on the electronic tag ID and the attribute information of the corresponding optical fiber network node; the attribute information includes a specific location and multiple attributes, each attribute includes multiple individuals; the modeling The modules are classified according to the same individual, and each type of virtual optical network node generates a fiber network cluster, which is modeled according to each fiber network cluster.

Preferably, the information interaction module reads the electronic tag ID and sends it to the management service module, and the management service module returns the fiber network cluster model data of the corresponding virtual fiber network node classified according to the facility; the information interaction module receives the model Data, call the display module to display the model.

Preferably, when the attribute is a facility, each facility is an individual, and the modeling module performs distributed sorting modeling on all virtual fiber network nodes in the same fiber network cluster according to specific locations; the attribute is When the fiber type, operator, plugging status, or age is exceeded, the management service module classifies and generates a fiber network cluster according to the same individual, and the modeling module classifies multiple virtual fiber network nodes in the same fiber network cluster in advance Set the order sort mode, or directly model without order.

Preferably, when the information interaction module reads the electronic tag ID and receives an input attribute corresponding to the optical fiber network node, it sends a request carrying both data to the management service module; the management service module returns the corresponding virtual fiber network node All attribute information of the; the information interaction module calls the display module to display all attribute information.

Preferably, when the information interaction module reads the electronic tag ID and receives all attribute information of the corresponding optical fiber network node, it associates the two to obtain the association information and sends it to the management service module; the management service module according to the association information Classification modeling.

Preferably, the attribute information further includes specific locations of other fiber network nodes associated with the corresponding fiber network node; the management service module establishes corresponding fiber network nodes and associated fiber networks according to the specific locations of other fiber network nodes Map channels between nodes, and establish an associated model of the fiber network cluster where the virtual fiber network nodes at both ends of the map channel are located, and assign a channel number to each mapped channel.

Preferably, when receiving the query of the associated model, the information interaction module sends the read electronic tag ID and the mapping channel of the query to the management service module; the management service module returns the cluster of the virtual optical network nodes at both ends of the mapping channel An associated model, and a mapping channel is displayed in the associated model.

At least one of the above technical solutions has the following advantages:

1. Each electronic tag has a unique electronic tag ID. After each electronic tag ID is associated with all attribute information of the corresponding fiber network node, the back-end server classifies the different facilities where the fiber network node is located in the association information, and according to The specific positions are ranked and modeled in each category. Reading the electronic tag ID through a mobile smart terminal can model the specific location of the corresponding fiber network node in the facility, making the fiber network node display more intuitive, on-site construction personnel can quickly and accurately find the specified fiber network node, and improve the entire fiber network deployment And maintenance efficiency.

2. The background server establishes a corresponding virtual fiber network node according to each associated information, and realizes the unification of the network and platform of the passive fiber network node through the background. The back-end server establishes a mapping channel between the corresponding fiber network node and the associated fiber network node, and assigns a channel number to each mapping channel to visualize the mapping channel and clarify the associated fiber network node.

3. The model includes links to all attribute information corresponding to the optical fiber network nodes. You can directly click to view all attributes. The electronic tag only needs to store the electronic tag ID, reducing the need for electronic tag memory space. The location and attributes of the optical fiber network node can be modified through the mobile intelligent terminal. The back-end server modifies the corresponding model to avoid rewriting the electronic label, further improving maintenance efficiency.

BRIEF DESCRIPTION

1 is a flowchart of a first embodiment of the present invention;

2 is a schematic diagram of the modeling process of the first embodiment of the present invention;

3 is a schematic diagram of the query process of the first embodiment of the present invention;

4 is a schematic flowchart of a second embodiment of the present invention;

5 is a schematic flowchart of a fifth embodiment of the present invention;

FIG. 6 is a system schematic diagram of a sixth embodiment of the present invention.

detailed description

The present invention will be further described in detail below with reference to the drawings and embodiments.

First embodiment

As shown in FIG. 1, the optical fiber network node management method of this embodiment includes a modeling process (as shown in FIG. 2) and a query process (as shown in FIG. 3), and specifically includes the steps:

S1. An electronic label is set for each optical network node, each electronic label has a unique electronic label ID, and the electronic label ID is associated with all attribute information of the corresponding optical network node.

Preferably, after reading the electronic tag ID through the mobile intelligent terminal, all attribute information corresponding to the optical fiber network node is input through the mobile intelligent terminal to obtain the association information.

S2. After the mobile intelligent terminal packages the associated information, it is reported to the background server. Preferably, the associated information is reported through the mobile cellular network.

S3. The back-end server is classified according to the different facilities where the fiber-optic network nodes are located in the associated information, and sorted and modeled in each class according to the specific location. At this point, the back-end server modeling process is completed.

Specifically, the attribute information of the optical fiber network node includes a specific location and multiple attributes, and each attribute includes multiple individuals. The back-end server generates a virtual fiber network node according to each associated information, and multiple virtual fiber network nodes are classified into one class according to the same individual to generate a fiber network cluster.

When the attribute is a facility, each facility is an individual. For example, if the facility is an optical distribution frame, then each optical distribution frame is an individual, and the virtual fiber network nodes located on the same optical distribution frame are classified into one category. Generate a fiber optic network cluster. For example, the virtual fiber network node located in the optical distribution frame 1 generates the first fiber network cluster, and the virtual fiber network node located in the optical distribution frame 2 generates the second fiber network cluster.

Then, all virtual fiber network nodes in the same fiber network cluster are modeled in a distributed order according to specific locations. Usually the specific location is the frame, disk and port number where the fiber network node is located, then the virtual fiber network node is ordered and modeled according to the frame, disk and port number to ensure the position of the virtual fiber network node on the model and the actual fiber network node There is a one-to-one correspondence at the location of the optical distribution frame.

Preferably, the facility may be a box or a box, etc. The specific location may be only a disk and a port number, or only a frame and a disk.

S4. As shown in FIG. 3, when querying the optical fiber network node, the mobile intelligent terminal reads the electronic tag ID and sends a query request containing the electronic tag ID to the backend server.

S5. The back-end server receives the query request and parses it, performs a matching search in the virtual optical fiber network node through the electronic tag ID in the query request, finds the corresponding virtual optical fiber network node and the optical fiber network cluster where it is located, and returns the generated model data to the mobile Intelligent Terminal.

S6. The mobile intelligent terminal receives the returned model data, displays the model, and displays the specific location of the corresponding fiber network node in the facility in the model, and the model includes links to all attribute information of the corresponding fiber network node.

Preferably, when the mobile intelligent terminal displays the model of the fiber optic network cluster, the virtual fiber network node corresponding to the read electronic tag ID is highlighted, as shown by the black dot in FIG. 3, the virtual fiber network node links all its attribute information, the user After clicking the highlighted virtual fiber network node, the mobile intelligent terminal can display all attribute information through a separate interface, and all attribute information can be displayed in the form of a chart.

Second embodiment

On the basis of the first embodiment, the optical fiber network node management method of this embodiment, as shown in FIG. 4, in the modeling process, after reading the electronic tag ID through a mobile smart terminal, the user inputs all the corresponding optical fiber network nodes. In the attribute information, you can also enter the specific location of other fiber network nodes connected to the corresponding fiber network node.

For example, the mobile smart terminal reads the electronic tag ID and enters the specific location of the corresponding optical fiber network node B as the 502 box 3 disk 5 port, and the specific location of the optical network node A connected with the optical fiber network node B as the 301 box 2 disk 5 Then, when the attribute information of the optical fiber network Node B is input, the port 5 of the 301 box 2 disk will be filled in as the associated key value.

After the background server receives the association information sent by the mobile intelligent terminal, multiple virtual fiber network nodes are classified into the same individual according to the same individual, and a fiber network cluster is generated. In addition, the background server establishes a mapping channel between the optical fiber network node corresponding to the electronic tag ID and the associated optical fiber network node according to the specific locations of the associated other optical fiber network nodes, and establishes the virtual fiber network nodes at both ends of the mapping channel. The associated model of the fiber optic network cluster, and then assign a channel number to each mapped channel.

As shown in FIG. 4, the background server has established a model of the fiber network cluster 1 where the virtual fiber network node A ′ (A ′ is a virtual node of the fiber network node A) is located, and the virtual fiber network node B ′ where the fiber network node B is generated is located After the fiber network cluster 2, according to the associated key value in the attribute information of the fiber network node B, between the fiber network cluster 2 and the fiber network cluster 1, a virtual fiber network node B 'and a virtual fiber network node A' are established The mapping channel of the two optical fiber network clusters establishes an association model. The background server can also supplement the associated key value of the fiber network node B in the attribute information of the fiber network node A.

After reading the electronic tag ID of the optical fiber network node A, the mobile intelligent terminal sends a query request containing the electronic tag ID to the backend server. The background server returns the model data of the optical fiber network cluster 1, and the mobile intelligent terminal displays the model of the optical fiber network cluster 1, and highlights the virtual optical fiber network node A '. At this time, if you click on the virtual fiber network node A ', two options can appear, one is to display all attribute information of the fiber network node A through a separate interface, and the other is to display the virtual fiber network node B' and the virtual fiber network node through a separate interface The associated model of A ', and the mapped channel is displayed in the associated model, and the channel will also be marked with the corresponding channel number.

Third embodiment

Based on the second embodiment, in this embodiment, there are multiple fiber network nodes connected to one fiber network node. When the mobile intelligent terminal inputs attribute information, it is necessary to input the associated key values separately. Value to find the corresponding virtual fiber network node and establish a mapping channel.

When the mobile intelligent terminal reads the electronic tag ID of the optical fiber network node, the background server returns the model of the optical fiber network cluster where the optical fiber network node is located (the model is classified and clustered according to the facility), and the corresponding virtual optical fiber is highlighted Network node. By clicking on the highlighted fiber network node, you can choose to display all attribute information, or all related virtual fiber network nodes. By selecting the virtual fiber network node to enter a separate interface, display the associated model of the two associated virtual fiber network nodes , Including mapping channel and channel number. Since the opposite virtual fiber network node in the association model links all its attribute information, when you click on the opposite virtual fiber network node, you can further display all the attribute information of the virtual fiber network node through a separate interface.

Fourth embodiment

Based on the above embodiments, the attribute information of the optical fiber network node includes a specific location and multiple attributes, and each attribute includes multiple individuals. In addition to facilities, attributes also include fiber type, operator, plug-in status, and age. The back-end servers are classified into the same individual based on these attributes and generate fiber-optic network clusters. The sorting order modeling of each attribute can be preset in the background server.

E.g,

All attribute information of the optical fiber network node A is: optical distribution frame: 1, optical fiber type: SC, operator: China Telecom, age: 3 years.

All attribute information of the optical fiber network node B is: optical distribution frame: 1, optical fiber type: LC, operator: China Telecom, age: 2 years.

For the optical fiber network node A and the optical fiber network node B, the optical distribution frame belongs to the facility, the facility is 1, belong to the same individual, can be classified into one category, generate a fiber network cluster, and sort according to specific locations in the fiber network cluster .

The optical fiber types of the two optical fiber network nodes are different. According to the individual classification, the optical fiber network node A is classified into the SC category, and the optical fiber network node B is classified into the LC category. In each category, the optical fiber network clusters are separately generated and modeled. In each optical fiber network cluster, there is no need to sort, or it can be sorted and modeled according to the preset order, such as the order of appearance time.

The operators of the two fiber network nodes are the same, and they can be classified into the same category and generate a fiber network cluster. This fiber network cluster can be modeled without ranking.

The ages of the two optical fiber network nodes are different, and they are classified and generated into optical fiber network clusters and modeled separately. They may not be sorted or may be sorted according to a preset order.

When the mobile smart terminal reads the electronic tag ID of a certain fiber network node, if a corresponding attribute is input, the mobile smart terminal sends a request message carrying the electronic tag ID and the attribute to the backend server, and the backend server searches according to the request message Go to the corresponding virtual fiber network node and the fiber network cluster where it is located, and return the model data to the mobile intelligent terminal, and the mobile intelligent terminal displays the model corresponding to the attribute.

For example, a mobile smart terminal reads the electronic tag ID of the optical fiber network node A, enters the attribute age, and the backend server returns the corresponding model in the optical fiber network cluster with an age of 3 years based on the electronic tag ID and age. data. The mobile intelligent terminal displays the corresponding model, and the user can use the model to view which fiber network nodes are in the same period.

Fifth embodiment

Based on the above embodiments, in this embodiment, when the mobile intelligent terminal displays the model of the optical fiber network cluster, the user can click the highlighted optical fiber network node and modify the optical fiber network node through the mobile intelligent terminal.

If it is to modify the attribute information, then click the highlighted fiber network node, select the mobile smart terminal to display all attribute information, and modify the attribute directly. The mobile terminal reports the modified attribute information and the corresponding electronic tag ID to the backend server. The backend server modifies the fiber network cluster where the corresponding virtual network fiber node is located according to the modified attribute, and modifies the model.

As shown in Figure 5, if the specific location is modified, when the mobile smart terminal displays the model of the fiber network cluster, the specific location of the highlighted virtual fiber node can be modified. Specifically, the mobile smart terminal directly Modified in the attribute information, the mobile intelligent terminal reports the specific location modification information and the electronic tag ID to the back-end server, and the back-end server reclassifies the virtual optical node according to the specific location modification information and the electronic tag ID, and the modified optical fiber network cluster Rebuild the model. If the modified virtual fiber node has associated virtual fiber nodes, the background server re-establishes the mapping channels of the two nodes and re-allocates the channel number. Then, the background server sends the modified model data to the mobile intelligent terminal, and the model of the optical fiber network cluster where the modified virtual network optical fiber node is located is highlighted on the mobile intelligent terminal.

Preferably, in all the above embodiments, the optical fiber network node includes ports, optical fiber cables, boxes and connectors used in the optical fiber network. The electronic label may be attached to the optical fiber network node in a plane, or may be embedded and installed in the optical fiber network node. The electronic tag is preferably an RFID tag, and the mobile smart terminal may be a mobile phone or a PAD (Portable Device); when an RFID tag is used, the mobile smart terminal may also be a special RFID handheld reader.

Sixth embodiment

Based on the above management method, this embodiment provides an optical fiber network node management system. As shown in FIG. 6, it includes an information interaction module, a management service module, a display module, and multiple electronic tags.

Each electronic tag has a unique ID and is installed on a fiber optic network node. Preferably, the fiber optic network node includes ports, fiber optic cables, boxes and connectors used in the fiber optic network. The electronic label may be attached to the optical fiber network node in a plane, or may be embedded and installed in the optical fiber network node.

The information interaction module is set in the mobile intelligent terminal, and is used to read the electronic tag ID, and also used for human-computer interaction with the user and mutual communication with the background server. Preferably, the information interaction module reads the electronic tag ID, receives all input attribute information of the corresponding optical fiber network node, associates the two to obtain the association information, and then sends the association information to the management service module, so that the management service module can model.

The management service module is set in the background server and is used to receive the electronic tag ID sent by the information interaction module and all the attribute information of the corresponding optical fiber network node. Sorting modeling.

The display module is set in the mobile intelligent terminal and is used to display the specific position and all attributes of the corresponding optical fiber network node in the model.

Preferably, the above management service module includes a transceiver module and a modeling module.

The transceiver module is used to receive the electronic tag ID sent by the information interaction module and the attribute information of the corresponding optical fiber network node; and also used to send the established model data to the information interaction module.

The modeling module is used to generate a virtual optical fiber network node according to the electronic tag ID and the attribute information of the corresponding optical fiber network node; the attribute information includes a specific location and multiple attributes, and each attribute includes multiple individuals. The modeling modules are grouped according to the same individual, and each type of virtual optical network node generates a fiber network cluster, which is modeled according to each fiber network cluster.

Preferably, when the attribute is a facility, each facility is an individual, and the modeling module performs distributed sorting modeling on all virtual fiber network nodes in the same fiber network cluster according to specific locations.

Preferably, when the attribute is the fiber type, operator, plugging status, or age, the management service module categorizes and generates the fiber network cluster according to the same individual, and the modeling module presses multiple virtual fiber network nodes in the same fiber network cluster Pre-set order sorting mode.

When the above information interaction module reads the electronic tag ID and sends it to the management service module, the transceiver module of the management service module receives the request carrying the electronic tag ID, and the modeling module searches for the fiber network cluster where the corresponding virtual fiber network node is located (this fiber network cluster is According to the clustering of facilities), and return the model data to the information interaction module through the transceiver module. After receiving the model data, the information interaction module calls the display module to display the corresponding model.

When the above information interaction module reads the electronic tag ID and receives a certain attribute of the corresponding fiber network node input by the user, it sends a request carrying both data to the transceiver module, and the modeling module searches for the corresponding fiber network cluster according to the attribute. The model data is returned to the information interaction module through the transceiver module. After receiving the model data, the information interaction module calls the display module to display the model corresponding to the attribute. The user can see which virtual fiber network nodes have the same attribute.

Seventh embodiment

Based on the sixth embodiment, in this embodiment, the information interaction module receives the attribute information input by the user, and further includes specific locations of other fiber network nodes connected to the corresponding fiber network node, that is, the associated key value . The transceiver module receives the attribute information containing the key value, and the modeling module establishes a mapping channel between the corresponding fiber network node and the associated fiber network node according to the virtual fiber network node corresponding to the key value, and establishes the two ends of the mapping channel The associated model of the fiber network cluster where the virtual fiber network node is located, and a channel number is assigned to each mapped channel.

When the display module displays the fiber network cluster model, if you receive a query of the associated model selected by the user; the information interaction module sends a query message to the transceiver module, and the modeling module finds the fiber network cluster where the connected fiber network node is located. Returns the data of the associated model of the cluster where the virtual optical network nodes at both ends of the mapping channel are located. After receiving the data, the mobile intelligent terminal displays the associated model and mapping channel through the display module.

Preferably, the user can directly modify the attribute information or the specific location of the optical fiber network node through the display module, and the modeling module of the management service module reclassifies and generates the optical fiber network cluster according to the modified content, and then re-modeling.

Eighth embodiment

In this embodiment, the port electronic label and the box electronic label are installed on a set of ODF (Optical Distribution Frame) equipment with 576 ports. The port electronic label is installed at the end of the 576 optical fiber connector line, the box The electronic tags are installed on the surface of each box, and all electronic tags use RFID tags. In this embodiment, the mobile intelligent terminal is an RFID handheld reader, and each electronic tag ID is read by the RFID handheld reader, all attribute information corresponding to each electronic tag ID is received, and the two are associated. The associated information is uploaded to the back-end server through the RFID handheld reader, and the back-end server generates a virtual fiber network node for each set of associated information. The background server classifies all virtual fiber network nodes according to their ODFs and cabinets. Each type forms a fiber network cluster. Multiple virtual fiber network nodes in each fiber network cluster are based on the specific locations of the frame, disk, and port number. Perform sequencing modeling. At the same time, the background server will also be classified and modeled according to the attributes such as manufacturer and age.

The RFID handheld reader reads the electronic tag of a certain port and reports it to the back-end server. The server delivers the model data of the optical fiber network cluster where the tag is located. This model is the model of the optical fiber network cluster sorted according to the specific location. RFID handheld reader The model is displayed to obtain the specific location and distribution of the port electronic tag on the ODF frame. Then, the user can modify the specific location of the port through the RFID handheld reader, and upload the modified information to the back-end server. The back-end server re-modifies the specific location of the port and updates the model.

The present invention is not limited to the above-mentioned embodiments. For those of ordinary skill in the art, without departing from the principles of the present invention, several improvements and retouches can be made. These improvements and retouches are also regarded as the protection of the present invention Within range. The contents that are not described in detail in this specification belong to the prior art known to those skilled in the art.

Claims

An optical fiber network node management method, characterized in that it includes the steps of:

Each optical network node is provided with an electronic label, and the electronic label ID is associated with all attribute information of the corresponding optical network node;

The background server is classified according to the different facilities where the fiber network nodes in the associated information are located, and sorted and modeled in each category according to the specific location;

After reading the electronic tag ID, the mobile intelligent terminal queries the back-end server and receives the returned data, and displays the specific location in the facility where the corresponding optical fiber network node is located through the model, and the model includes links to all attribute information of the corresponding optical fiber network node.
The optical fiber network node management method according to claim 1, wherein the associated information received by the background server includes: an electronic tag ID read by a mobile intelligent terminal, and a corresponding optical fiber network node input through the mobile intelligent terminal All attribute information.
The optical fiber network node management method according to claim 1, wherein:

The attribute information includes specific locations and multiple attributes, and each attribute includes multiple individuals;

The background server generates a virtual fiber network node according to each associated information; a plurality of virtual fiber network nodes are grouped together according to the same individual to generate a fiber network cluster.
The optical fiber network node management method according to claim 3, wherein the attributes of the attribute information further include optical fiber type, operator, plugging and unplugging status and age, and the background server is classified according to the same individual and generates an optical fiber network Cluster, multiple virtual fiber network nodes in the same fiber network cluster are sorted and modeled in a preset order, or directly modeled without order.
The optical fiber network node management method according to claim 3, characterized in that: when the attribute is a facility, each facility is an individual, and all virtual optical network nodes in the same optical fiber network cluster in the background server are based on the specific Distributed ranking modeling for locations.
The optical fiber network node management method according to claim 5, wherein the mobile intelligent terminal reads the electronic tag ID to query the background server and receives the returned data specifically including:

The mobile intelligent terminal sends a query request carrying the electronic tag ID to the back-end server, the back-end server searches for the fiber-optic network cluster corresponding to the virtual fiber-optic network node classified according to the facility, and returns the corresponding virtual fiber-network node model data in the fiber-optic network cluster Mobile smart terminal.
The optical fiber network node management method according to claim 6, wherein the mobile intelligent terminal receives the data returned by the background server and displays the model, wherein the specific location of all virtual optical network nodes and the specific location of the actual optical network node are One correspondence.
The optical fiber network node management method according to claim 6, wherein when the mobile intelligent terminal displays the model of the optical fiber network cluster, the virtual optical network node corresponding to the read electronic tag ID is highlighted, and the virtual optical network node is linked All its attribute information, and all attribute information is displayed through a separate interface.
The optical fiber network node management method according to claim 5, characterized in that:

The attribute information further includes specific locations of other fiber network nodes connected to the corresponding fiber network nodes;

The background server establishes a mapping channel between the corresponding fiber network node and the associated fiber network node according to the specific positions of the other fiber network nodes, and establishes a fiber network cluster where the virtual fiber network nodes at both ends of the mapping channel are located Associate the model, and assign a channel number to each mapped channel.
The optical fiber network node management method according to claim 9, wherein the model displayed by the mobile intelligent terminal highlights the virtual optical network node corresponding to the read electronic tag ID, the virtual optical network node according to the selection, through A separate interface displays all of its attribute information, or displays the associated model through a separate interface, and the associated model displays a mapping channel.
The optical fiber network node management method according to claim 10, wherein when there is more than one associated model, the corresponding associated model is selected and displayed by the associated virtual optical fiber network node, and the opposite end in the associated model The virtual fiber network node links all its attribute information.
The optical fiber network node management method according to claim 8 or 10, wherein when the mobile intelligent terminal displays all attribute information of the virtual optical network node, if the attribute information is modified, the mobile intelligent terminal will modify the modified attribute information It is reported to the back-end server, and the back-end server reclassifies the virtual optical node according to the modified attribute information, and modifies the model of the fiber network cluster where the reclassification is located.
The optical fiber network node management method according to claim 8 or 10, characterized in that: when the mobile intelligent terminal displays the model of the optical fiber network cluster, if the specific location modification information of the highlighted virtual optical fiber node is received, the mobile intelligent terminal The specific location modification information and the electronic tag ID are reported to the back-end server. The back-end server modifies the information and the electronic tag ID according to the specific location, reclassifies the virtual optical node and rebuilds the model.
The optical fiber network node management method according to any one of claims 1-11, wherein: the optical fiber network node includes ports, optical fiber cables, boxes and connectors used in the optical fiber network; the electronic label plane It is attached to the optical fiber network node or embedded in the optical fiber network node.
An optical fiber network node management system, which is characterized by comprising:

Multiple electronic tags, each with a unique ID and installed on a fiber optic network node;

An information interaction module, which is installed in the mobile intelligent terminal, is used to read the electronic tag ID and communicate with the user and the background server;

The management service module, which is set in the background server, is used to receive the electronic tag ID and all attribute information of the corresponding optical fiber network node sent by the information interaction module, classify according to different facilities where the optical fiber network node is located, and according to the specific location Ranking modeling in each category;

The display module, which is set in the mobile intelligent terminal, is used to display the specific position and all attributes of the corresponding optical fiber network node in the model.
The optical fiber network node management system according to claim 15, wherein the management service module comprises:

The transceiver module is used to receive the electronic tag ID sent by the information interaction module and the attribute information of the corresponding optical fiber network node; it is also used to send the established model data to the information interaction module;

A modeling module, which is used to generate a virtual optical fiber network node based on the electronic tag ID and the attribute information of the corresponding optical fiber network node; the attribute information includes a specific location and multiple attributes, each attribute includes multiple individuals; the modeling The modules are classified according to the same individual, and each type of virtual optical network node generates a fiber network cluster, which is modeled according to each fiber network cluster.
The optical fiber network node management system according to claim 16, wherein:

The information interaction module reads the electronic tag ID and sends it to the management service module, and the management service module returns the model data of the optical fiber network cluster corresponding to the virtual fiber network node classified according to the facility; the information interaction module receives the model data and calls The display module displays the model.
The optical fiber network node management system according to claim 16, wherein:

When the attribute is a facility, each facility is an individual, and the modeling module models all virtual fiber network nodes in the same fiber network cluster according to specific locations in a distributed ordering model;

When the attribute is the fiber type, operator, plugging and unplugging status or age, the management service module classifies and generates a fiber network cluster according to the same individual, and the modeling module divides multiple virtual fibers in the same fiber network cluster The network nodes are sorted according to the preset order, or directly modeled without order.
The optical fiber network node management system according to claim 18, wherein the information interaction module reads the electronic tag ID and receives a certain attribute corresponding to the input optical fiber network node, and sends a request carrying both data to the management Service module; the management service module returns all attribute information corresponding to the virtual fiber network node; the information interaction module calls the display module to display all attribute information.
The optical fiber network node management system according to claim 16, wherein the information interaction module reads the electronic tag ID and receives all the attribute information of the input corresponding optical fiber network node, associates the two to obtain the associated information and sends it to the Management service module; the management service module is classified and modeled according to the associated information.
The optical fiber network node management system according to claim 16, wherein:

The attribute information further includes specific locations of other fiber network nodes connected to the corresponding fiber network nodes;

The management service module establishes a mapping channel between the corresponding fiber network node and the associated fiber network node according to the specific positions of other fiber network nodes, and establishes the association of the fiber network cluster where the virtual fiber network nodes at both ends of the mapping channel are located Model, and assign a channel number to each mapped channel.
The optical fiber network node management system according to claim 21, characterized in that: when receiving the query of the associated model, the information interaction module sends the read electronic tag ID and the mapping channel of the query to the management service module; the management The service module returns the association model of the cluster where the virtual optical network nodes at both ends of the mapping channel are located, and the mapping channel is displayed in the association model.
The optical fiber network node management system according to any one of claims 15-22, wherein: the optical fiber network node includes ports used in the optical fiber network, optical fiber cable, box and connector; the electronic label plane It is attached to the optical fiber network node or embedded in the optical fiber network node.