CN109618250B - Optical fiber network node management method and system - Google Patents

Abstract

A method and a system for managing optical network nodes relate to the field of optical network communication and comprise the following steps: each optical network node is provided with an electronic tag, and the ID of the electronic tag is associated with all attribute information of the corresponding optical network node; the background server classifies different facilities where the optical network nodes are located according to the associated information, and models the optical network nodes in each class according to specific positions in a sequencing mode; and the mobile intelligent terminal queries the background server after reading the electronic tag ID and receives the returned data, and displays the specific position of the corresponding optical network node in the facility through the model, wherein the model comprises links of all attribute information of the corresponding optical network node. The invention can quickly and accurately position the position of the appointed optical fiber network node, reduce the requirement of the memory space of the electronic tag and improve the deployment and maintenance efficiency of the whole optical fiber network.

Description

Optical fiber network node management method and system

Technical Field

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

Background

In the traditional optical fiber network management system, an optical fiber port and a box are both passive nodes, the management mode of the optical fiber and the box is mainly marked by an artificial paper label, the management mode is low in efficiency, information is easy to make mistakes and lose, and along with the continuous development of the internet of things technology and big data, an efficient management mode for electronization and platform of the optical fiber network nodes is urgently needed.

For the management of the optical network nodes, many manufacturers propose their solutions, some of which use a Radio Frequency Identification (RFID) technology, that is, an RFID collector collects information of an electronic tag, and the collected data is uploaded to a background server for storage. The premise for realizing the method is as follows: the electronic tag is arranged on each element to be managed, and at least one attribute content is written into each electronic tag, so that the electronic tag is required to have a writable memory space, and the electronic tag is required to be rewritten before each element is deployed and maintained, so that the deployment and maintenance efficiency of the whole optical fiber network is reduced.

In addition, the data uploaded to the background server is stored in an isolated database mode, and the data stored by the background server is called by the front-end acquisition equipment and is presented to the user in a text mode. Therefore, in the intensive scene of the optical fiber network nodes, the positions of the designated optical fiber network nodes cannot be quickly and accurately positioned, and meanwhile, when the optical fiber network nodes are very large in data, the searching and the associated searching of the nodes take a lot of time.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a method and a system for managing optical network nodes, which can quickly and accurately position the position of the specified optical network node, reduce the requirement of an electronic tag memory space and improve the efficiency of the whole optical network deployment and maintenance.

In order to achieve the above object, in one aspect, the technical solution adopted is a method for managing optical network nodes, including the steps of:

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

the background server classifies different facilities where the optical network nodes are located according to the associated information, and models the optical network nodes in each class according to specific positions in a sequencing mode;

and the mobile intelligent terminal queries the background server after reading the electronic tag ID and receives the returned data, and displays the specific position of the corresponding optical network node in the facility through the model, wherein the model comprises links of all attribute information of the corresponding optical network node.

Preferably, the association 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 network nodes input through the mobile intelligent terminal.

Preferably, the attribute information includes a specific location and a plurality of attributes, each attribute including a plurality of individuals; the background server generates a virtual optical fiber network node according to each piece of associated information; and the plurality of virtual optical fiber network nodes are classified into one class according to the same individual to generate an optical fiber network cluster.

Preferably, the attributes of the attribute information further include an optical fiber type, an operator, a plugging state and a period, the background server is classified according to the same individual and generates an optical fiber network cluster, and a plurality of virtual optical fiber network nodes in the same optical fiber network cluster are modeled in a preset sequence or directly modeled without the sequence.

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

Preferably, the querying the background server and receiving the return data after the mobile intelligent terminal reads the electronic tag ID specifically includes: the mobile intelligent terminal sends a query request carrying the electronic tag ID to the background server, the background server searches the optical fiber network clusters classified by the corresponding virtual optical fiber network nodes according to facilities, and returns model data of the corresponding virtual optical fiber network nodes in the optical fiber network clusters 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 the virtual optical fiber network nodes correspond to the specific positions of the actual optical fiber network nodes one to one.

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, the virtual optical fiber network node links all the attribute information thereof, and all the attribute information is displayed through a single interface.

Preferably, the attribute information further includes specific locations of other optical network nodes associated with the corresponding optical network node; and the background server establishes mapping channels between the corresponding optical fiber network nodes and the associated optical fiber network nodes according to the specific positions of the other optical fiber network nodes, establishes an association model of an optical fiber network cluster in which the virtual optical fiber network nodes at the two ends of the mapping channels are positioned, and distributes channel numbers to each mapping channel.

Preferably, in the model displayed by the mobile intelligent terminal, the virtual optical network node corresponding to the read electronic tag ID is highlighted, and according to the selection, the virtual optical network node displays all attribute information thereof through a single interface, or displays the association model through a single interface, and displays a mapping channel in the association model.

Preferably, when there is more than one association model, the corresponding association model is selected for display through the associated virtual optical fiber network node, and the opposite virtual optical fiber network node in the association model links all the attribute information thereof.

Preferably, when the mobile intelligent terminal displays all the attribute information of the virtual optical network node, if the attribute information is modified, the mobile intelligent terminal reports the modified attribute information to the background server, and the background server reclassifies the virtual optical node according to the modified attribute information and modifies the model of the optical network cluster in which the virtual optical node is reclassified.

Preferably, when the mobile intelligent terminal displays the model of the optical fiber network cluster, if the highlighted specific position modification information of the virtual optical fiber node is received, the mobile intelligent terminal reports the specific position modification information and the electronic tag ID to the background server, and the background server reclassifies and reconstructs the model of the virtual optical node according to the specific position modification information and the electronic tag ID.

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

In another aspect, a fiber network node management system is provided, including:

a plurality of electronic tags, each electronic tag having a unique ID and being installed at a fiber optic network node;

the information interaction module is arranged in the mobile intelligent terminal and used for reading the ID of the electronic tag and communicating with the user and the background server;

the management service module is arranged in the background server and used for receiving the electronic tag ID and all attribute information of the corresponding optical fiber network nodes sent by the information interaction module, classifying the electronic tag ID and all attribute information according to different facilities where the optical fiber network nodes are located, and performing sequencing modeling in each class according to specific positions;

and the display module is arranged in the mobile intelligent terminal and is used for displaying the specific position and all attributes of the corresponding optical network node in the model.

Preferably, the management service module includes:

the receiving and sending module is used for receiving the electronic tag ID and the attribute information of the corresponding optical network node sent by the information interaction module; the system is also used for sending the established model data to the information interaction module;

the modeling module is used for generating a virtual optical network node according to the electronic tag ID and the attribute information of the corresponding optical network node; the attribute information comprises a specific position and a plurality of attributes, and each attribute comprises a plurality of individuals; the modeling module is classified according to the same individual, each type of virtual optical network node generates an optical fiber network cluster, and modeling is carried out according to each optical fiber network cluster.

Preferably, the information interaction module reads the electronic tag ID and sends the electronic tag ID to the management service module, and the management service module returns optical fiber network cluster model data classified by the corresponding virtual optical fiber network node according to facilities; and the information interaction module receives the model data and calls a display module to display the model.

Preferably, when the attributes are facilities, each facility is an individual, and the modeling module performs distributed sequencing modeling on all virtual optical fiber network nodes in the same optical fiber network cluster according to specific positions; when the attributes are optical fiber types, operators, plug-in and pull-out states or years, the management service module classifies and generates an optical fiber network cluster according to the same individual, and the modeling module sequences the plurality of virtual optical fiber network nodes in the same optical fiber network cluster according to a preset sequence or directly models without sequencing.

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

Preferably, the information interaction module reads the electronic tag ID, and when receiving all input attribute information of the corresponding optical network node, associates the electronic tag ID and the attribute information to obtain associated information, and sends the associated information to the management service module; and the management service module classifies and models according to the associated information.

Preferably, the attribute information further includes specific locations of other optical network nodes associated with the corresponding optical network node; the management service module establishes mapping channels between corresponding optical network nodes and associated optical network nodes according to the specific positions of other optical network nodes, establishes an association model of an optical network cluster in which virtual optical network nodes at two ends of the mapping channels are located, and distributes channel numbers to each mapping channel.

Preferably, when the information interaction module receives the query of the association model, the information interaction module sends the read electronic tag ID and the queried mapping channel to the management service module; and the management service module returns the association model of the cluster where the virtual optical network nodes at the two ends of the mapping channel are located, and the mapping channel is displayed in the association model.

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

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 optical fiber network node, the background server classifies different facilities where the optical fiber network node is located according to the associated information, and models are ordered and modeled in each class according to specific positions. The electronic tag ID is read through the mobile intelligent terminal, the specific position of the corresponding optical network node in the facility can be displayed in a model mode, the optical network node display is more visual, field construction personnel can quickly and accurately find the appointed optical network node, and the deployment and maintenance efficiency of the whole optical network is improved.

2. The background server establishes a corresponding virtual optical fiber network node according to each piece of associated information, and networking and platform unification of passive optical fiber network nodes is realized through the background. The background server establishes mapping channels between the corresponding optical fiber network nodes and the associated optical fiber network nodes, and distributes a channel number to each mapping channel, so that the mapping channels are visualized, and the associated optical fiber network nodes are defined.

3. The model comprises links corresponding to all attribute information of the optical network nodes, all attributes can be checked by directly clicking, only the electronic tag ID needs to be stored in the electronic tag, and the requirement on the memory space of the electronic tag is reduced. The position and the attribute of the optical fiber network node can be modified through the mobile intelligent terminal, the background server modifies the corresponding model, the electronic tag is prevented from being rewritten, and the maintenance efficiency is further improved.

Drawings

FIG. 1 is a flow chart of a first embodiment of the present invention;

FIG. 2 is a schematic diagram of a modeling process according to a first embodiment of the invention;

FIG. 3 is a diagram illustrating a query process according to a first embodiment of the present invention;

FIG. 4 is a schematic flow chart of a second embodiment of the present invention;

FIG. 5 is a schematic flow chart of a fifth embodiment of the present invention;

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

Detailed Description

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

First embodiment

As shown in fig. 1, the method for managing optical network nodes in this embodiment includes a modeling process (shown in fig. 2) and an inquiry process (shown in fig. 3), and specifically includes the steps of:

s1, setting an electronic tag for each optical fiber network node, wherein each electronic tag has a unique electronic tag ID, and associating the electronic tag ID with all attribute information of the corresponding optical fiber network node.

Preferably, after the mobile intelligent terminal reads the electronic tag ID, all attribute information of the corresponding optical network node is input through the mobile intelligent terminal, and the associated information is obtained.

And S2, the mobile intelligent terminal packs the associated information and reports the associated information to the background server. Preferably, the association information is reported through the mobile cellular network.

And S3, the background server classifies different facilities where the optical network nodes are located according to the associated information, and performs sequencing modeling in each class according to specific positions, so that the modeling process of the background server is completed.

Specifically, the attribute information of the optical fiber network node includes a specific location and a plurality of attributes, and each attribute includes a plurality of individuals. The background server generates a virtual optical fiber network node according to each piece of association information, and the plurality of virtual optical fiber network nodes are classified into one type according to the same individual to generate an optical fiber network cluster.

When the attribute is the facility, each facility is an individual, for example, the facility is an optical distribution frame, each optical distribution frame is an individual, and the virtual optical fiber network nodes located in the same optical distribution frame are classified into one type to generate an optical fiber network cluster. For example, a virtual fiber network node located in the optical distribution frame 1 creates a first fiber network cluster, and a virtual fiber network node located in the optical distribution frame 2 creates a second fiber network cluster.

And then, carrying out distributed sequencing modeling on all virtual optical fiber network nodes in the same optical fiber network cluster according to specific positions. Generally, the specific positions are the frame, the disc and the port number where the optical fiber network node is located, and then the virtual optical fiber network node is ordered and modeled according to the frame, the disc and the port number, so as to ensure that the position of the virtual optical fiber network node on the model corresponds to the position of the actual optical fiber network node on the optical distribution frame one to one.

Preferably, the facility can be a box or a box, and the specific position can be only a disc and a port number, or only a frame and a disc.

S4, as shown in FIG. 3, when the optical network node is queried, the mobile intelligent terminal reads the electronic tag ID and sends a query request containing the electronic tag ID to the background server.

And S5, the background server receives and analyzes the query request, performs matching search in the virtual optical fiber network nodes through the electronic tag ID in the query request, finds out the corresponding virtual optical fiber network nodes and the optical fiber network cluster where the virtual optical fiber network nodes are located, and returns the generated model data to the mobile intelligent terminal.

And S6, the mobile intelligent terminal receives the returned model data, displays the model, and displays the specific position of the corresponding optical network node in the facility in the model, wherein the model comprises links of all attribute information of the corresponding optical network node.

Preferably, when the mobile intelligent terminal displays the model of the optical fiber network cluster, highlighting the virtual optical fiber network node corresponding to the read electronic tag ID, for example, a black dot in fig. 3, and the virtual optical fiber network node links all the attribute information thereof, and after the user clicks the highlighted virtual optical fiber network node, the mobile intelligent terminal may display all the attribute information through a separate interface, and all the attribute information may be displayed in the form of a graph.

Second embodiment

On the basis of the first embodiment, in the optical network node management method of this embodiment, as shown in fig. 4, in the modeling process, after a user reads an electronic tag ID through a mobile intelligent terminal, in inputting all attribute information of a corresponding optical network node, a specific position of another optical network node associated with the corresponding optical network node may also be input.

For example, the mobile intelligent terminal reads the electronic tag ID, and inputs the specific location of the corresponding optical network node B as 502 frame 3 disc 5 port, and the specific location of the optical network node a associated with the optical network node B as 301 frame 2 disc 5 port, so that when the attribute information of the optical network node B is input, the 301 frame 2 disc 5 port is filled as the associated key value.

After the background server receives the association information sent by the mobile intelligent terminal, the plurality of virtual optical fiber network nodes are classified into one type according to the same individual, and an optical fiber network cluster is generated. And the background server establishes mapping channels between the optical fiber network nodes corresponding to the electronic tag ID and the associated optical fiber network nodes according to the specific positions of the associated other optical fiber network nodes, establishes an association model of an optical fiber network cluster where the virtual optical fiber network nodes at the two ends of the mapping channels are located, and then distributes channel numbers to each mapping channel.

As shown in fig. 4, after the background server has established a model of the optical fiber network cluster 1 in which the virtual optical fiber network node a ' (a ' is a virtual node of the optical fiber network node a) is located, and generates the optical fiber network cluster 2 in which the virtual optical fiber network node B ' of the optical fiber network node B is located, according to the associated key value in the attribute information of the optical fiber network node B, a mapping channel between the virtual optical fiber network node B ' and the virtual optical fiber network node a ' is established between the optical fiber network cluster 2 and the optical fiber network cluster 1, and an association model is established between the two optical fiber network clusters. The background server may also supplement the associated key value of the optical network node B in the attribute information of the optical network node a.

And 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 background server. The background server returns the model data of the optical fiber network cluster 1, 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 the virtual optical network node a ' is clicked, two options may occur, one is to display all attribute information of the optical network node a through a single interface, and the other is to display the association model of the virtual optical network node B ' and the virtual optical network node a ' through a single interface, and display the mapping channel in the association model, and the channel may also mark the corresponding channel number.

Third embodiment

On the basis of the second embodiment, in this embodiment, there are a plurality of optical network nodes associated with one optical network node, the mobile intelligent terminal needs to input associated key values when inputting attribute information, and the background server finds a corresponding virtual optical network node according to each key value and establishes a mapping channel.

When the mobile intelligent terminal reads the electronic tag ID of the optical fiber network node, the background server returns a model (the model is classified and clustered according to facilities) of the optical fiber network cluster where the optical fiber network node is located, and highlights the corresponding virtual optical fiber network node. By clicking on the highlighted optical network node, all attribute information can be selected to be displayed, or all associated virtual optical network nodes are selected, and the virtual optical network node enters a single interface to display the association models of two associated virtual optical network nodes, wherein the association models comprise mapping channels and channel numbers. Since the opposite-end virtual optical fiber network node in the association model is linked with all the attribute information thereof, when the opposite-end virtual optical fiber network node is clicked, all the attribute information of the virtual optical fiber network node can be further displayed through a single interface.

Fourth embodiment

Based on the above embodiments, the attribute information of the optical network node includes a specific location and a plurality of attributes, each attribute including a plurality of individuals. The attributes include the fiber type, the operator, the plugging state, the age and the like besides the facilities, and the background server classifies the same individuals into one class according to the attributes and generates the fiber network cluster. The background server can preset the modeling of the sequencing order of each attribute.

For example,

all attribute information of the optical network node a is, optical distribution frame: 1, optical fiber type: SC, operator: china telecom, year limit: for 3 years.

All attribute information of the optical fiber network node B is that an optical distribution frame is 1, the optical fiber type is L C, an operator is China telecom, and the year is 2.

For the optical fiber network node a and the optical fiber network node B, the optical distribution frames belong to facilities, the facilities are 1, belong to the same individual, can be classified into one class, generate an optical fiber network cluster, and sort according to specific positions in the optical fiber network cluster.

The optical fiber types of the two optical fiber network nodes are different and are classified according to individuals, the optical fiber network node A is classified into SC type, the optical fiber network node B is classified into L C type, and in each type, an optical fiber network cluster is generated respectively, and during modeling, sequencing modeling can be performed in each optical fiber network cluster without sequencing or according to a preset sequence, such as the sequence of departure time and the like.

The operators of the two optical network nodes are the same, and can be classified into the same class, and an optical network cluster is generated, and the optical network cluster can be modeled without sequencing.

And the two optical fiber network nodes are different in age, are respectively classified to generate the optical fiber network clusters and are modeled, and can be not sequenced or sequenced according to a preset sequence.

When the mobile intelligent terminal reads the electronic tag ID of a certain optical fiber network node, if a corresponding attribute is input, the mobile intelligent terminal sends a request message carrying the electronic tag ID and the attribute to the background server, the background server finds the corresponding virtual optical fiber network node and the optical fiber network cluster where the virtual optical fiber network node is located according to the request message, model data is returned to the mobile intelligent terminal, and the mobile intelligent terminal displays the model corresponding to the attribute.

For example, the mobile intelligent terminal reads the electronic tag ID of the optical fiber network node a, inputs the attribute year, and the background server returns corresponding model data according to the electronic tag ID and the year, where the optical fiber network node a is in the optical fiber network cluster with the year of 3. The mobile intelligent terminal displays the corresponding model, and a user can check the same year and the optical network nodes through the model.

Fifth embodiment

On the basis of the foregoing embodiments, in this embodiment, when the mobile intelligent terminal displays the model of the optical network cluster, the user may click the highlighted optical network node, and modify the optical network node through the mobile intelligent terminal.

If the attribute information is modified, after the highlighted optical fiber network node is clicked, the mobile intelligent terminal is selected to display all the attribute information, and the attribute is directly modified. The mobile terminal reports the modified attribute information and the corresponding electronic tag ID to the background server, and the background server modifies the optical fiber network cluster where the corresponding virtual network optical fiber node is located according to the modified attribute and modifies the model.

As shown in fig. 5, if the specific location is modified, when the mobile intelligent terminal displays the model of the optical fiber network cluster, the specific location of the highlighted virtual optical fiber node can be modified, specifically, the specific location is modified directly in the attribute information by the mobile intelligent terminal, the mobile intelligent terminal reports the specific location modification information and the electronic tag ID to the background server, the background server reclassifies the virtual optical node according to the specific location modification information and the electronic tag ID, and reconstructs the model of the modified optical fiber network cluster. And if the modified virtual optical fiber nodes have the associated virtual optical fiber nodes, the background server reestablishes the mapping channels of the two nodes and redistributes the channel numbers. And then, the background server sends the modified and reconstructed model data to the mobile intelligent terminal, and the model of the optical fiber network cluster where the modified virtual network optical fiber nodes are located is highlighted on the mobile intelligent terminal.

Preferably, in all of the above embodiments, the optical network nodes include ports, optical fiber cables, boxes and connectors used in the optical network. The electronic tag can be attached to the optical fiber network node in a planar mode or can be installed in the optical fiber network node in an embedded mode. The electronic tag is preferably an RFID tag, and the mobile intelligent terminal can be a mobile phone or a PAD (Portable Device); when the RFID tag is adopted, the mobile intelligent terminal can also be a special RFID handheld reader.

Sixth embodiment

Based on the management method, this embodiment provides an optical network node management system, as shown in fig. 6, which includes an information interaction module, a management service module, a display module, and a plurality of electronic tags.

Each electronic tag has a unique ID and is installed on a fiber optic network node. Preferably, the optical network node comprises a port, an optical fiber cable, a box and a connector used in the optical network. The electronic tag can be attached to the optical fiber network node in a planar mode or can be installed in the optical fiber network node in an embedded mode.

The information interaction module is arranged in the mobile intelligent terminal and used for reading the ID of the electronic tag, performing man-machine interaction with a user and performing 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 network node, associates the attribute information with the electronic tag ID to obtain associated information, and then sends the associated information to the management service module, so that the management service module performs modeling.

The management service module is arranged in the background server and used for receiving the electronic tag ID and all attribute information of the corresponding optical fiber network nodes sent by the information interaction module, classifying the electronic tag ID and all attribute information according to different facilities where the optical fiber network nodes are located, and sequencing and modeling in each class according to specific positions.

The display module is arranged in the mobile intelligent terminal and used for displaying the specific position and all attributes of the corresponding optical network node in the model.

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

The receiving and sending module is used for receiving the electronic tag ID and the attribute information of the corresponding optical network node sent by the information interaction module; and the model data is also used for sending the established model data to the information interaction module.

The modeling module is used for generating a virtual optical network node according to the electronic tag ID and the attribute information of the corresponding optical network node; the attribute information includes a specific location and a plurality of attributes, each attribute including a plurality of individuals. The modeling module classifies the same individual into one class, each class of virtual optical network node generates an optical fiber network cluster, and modeling is carried out according to each optical fiber network cluster.

Preferably, when the attributes are facilities, each facility is an individual, and the modeling module performs distributed sequencing modeling on all virtual optical network nodes in the same optical network cluster according to specific positions.

Preferably, when the attributes are optical fiber types, operators, plug-in/pull-out states or age limits, the management service module classifies and generates optical fiber network clusters according to the same individual, and the modeling module orders the modules of the plurality of virtual optical fiber network nodes in the same optical fiber network cluster according to a preset sequence.

When the information interaction module reads the electronic tag ID and sends the electronic tag ID to the management service module, the transceiver module of the management service module receives a request carrying the electronic tag ID, the modeling module searches an optical fiber network cluster where the corresponding virtual optical fiber network node is located (the optical fiber network cluster is clustered according to facilities), model data are returned to the information interaction module through the transceiver module, and the information interaction module calls the display module to display the corresponding model after receiving the model data.

When the information interaction module reads the electronic tag ID and receives a certain attribute of the corresponding optical fiber network node input by a user, a request carrying data of the electronic tag ID and the attribute is sent to the transceiving module, the modeling module searches the corresponding optical fiber network cluster according to the attribute, model data are returned to the information interaction module through the transceiving module, the information interaction module receives the model data and calls the display module to display the model corresponding to the attribute, and the user can see the virtual optical fiber network nodes with the same attribute.

Seventh embodiment

On the basis of the sixth embodiment, in this embodiment, the information interaction module receives attribute information input by a user, and further includes specific positions of other optical network nodes associated with the corresponding optical network node, that is, associated key values. The receiving and sending module receives the attribute information containing the key value, the modeling module establishes mapping channels between corresponding optical fiber network nodes and the associated optical fiber network nodes according to the virtual optical fiber network nodes corresponding to the key value, establishes an association model of an optical fiber network cluster where the virtual optical fiber network nodes at two ends of the mapping channels are located, and distributes channel numbers to each mapping channel.

When the display module displays the optical fiber network cluster model, if the query of the associated model selected by the user is received; the information interaction module sends a query message to the transceiver module, the modeling module searches for an optical network cluster where the associated optical network node is located, and returns data of an association model of the cluster where the virtual optical network nodes at two ends of the mapping channel are located through the transceiver module. And after receiving the data, the mobile intelligent terminal displays the association model and the mapping channel through the display module.

Preferably, the user can directly modify the attribute information or the specific position 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 remodels.

Eighth embodiment

In the embodiment, port electronic tags and box electronic tags are installed on a set of ODF (Optical Distribution Frame) equipment with 576 ports, the port electronic tags are installed at the 576 Optical fiber connector line ends, the box electronic tags are installed on the surface of each box, and all the electronic tags are RFID tags. In this embodiment, the mobile intelligent terminal is an RFID handheld reader, and reads each electronic tag ID through the RFID handheld reader, receives all attribute information corresponding to each electronic tag ID, and associates the two. The associated information is uploaded to a background server through the RFID handheld reader, and the background server generates each group of associated information into a virtual optical fiber network node. And the background server classifies all the virtual optical fiber network nodes according to the ODF and the box body, each type forms an optical fiber network cluster, and a plurality of virtual optical fiber network nodes in each optical fiber network cluster are sequenced and modeled according to the specific positions of a frame, a disc and a port number. Meanwhile, according to attributes such as manufacturers and years, the background server can be classified and modeled.

The RFID handheld reader reads an electronic tag of a certain port and reports the electronic tag to a background server, the server issues model data of an optical fiber network cluster where the tag is located, the model is the model of the optical fiber network cluster which is sequenced according to a specific position, and the RFID handheld reader displays the model to obtain the specific position and distribution of the electronic tag of the port on the ODF frame body. Then, the user can modify the specific position of the port through the RFID handheld reader, the modified information is uploaded to the background server, the background server modifies the specific position of the port again, and the model is updated.

The present invention is not limited to the above-described embodiments, and it will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the principle of the present invention, and such modifications and improvements are also considered to be within the scope of the present invention. Those not described in detail in this specification are within the skill of the art.

Claims (21)

1. A method for managing nodes in an optical network, comprising the steps of:

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

the background server classifies different facilities where the optical network nodes are located according to the associated information, and models the optical network nodes in each class according to specific positions in a sequencing mode;

the mobile intelligent terminal queries the background server after reading the electronic tag ID and receives the returned data, the specific position of the corresponding optical fiber network node in the facility is displayed through the model, and the model comprises links of all attribute information of the corresponding optical fiber network node;

the attribute information comprises a specific position and a plurality of attributes, and each attribute comprises a plurality of individuals;

the background server generates a virtual optical fiber network node according to each piece of associated information; and the plurality of virtual optical fiber network nodes are classified into one class according to the same individual to generate an optical fiber network cluster.

2. The fiber optic network node management method of claim 1, wherein the association information received by the backend server comprises: the electronic tag ID read by the mobile intelligent terminal and all attribute information of the corresponding optical network nodes input through the mobile intelligent terminal.

3. The fiber optic network node management method of claim 2, wherein: the attributes of the attribute information further comprise optical fiber types, operators, plugging states and ages, the background server is classified according to the same individual and generates an optical fiber network cluster, and a plurality of virtual optical fiber network nodes in the same optical fiber network cluster are modeled in a preset sequence or directly modeled without the sequence.

4. The fiber optic network node management method of claim 1, wherein: and when the attributes are facilities, each facility is an individual, and in the background server, all the virtual optical fiber network nodes in the same optical fiber network cluster are subjected to distributed sequencing modeling according to specific positions.

5. The optical fiber network node management method of claim 4, wherein the querying a background server and receiving return data after the mobile intelligent terminal reads the electronic tag ID specifically comprises:

the mobile intelligent terminal sends a query request carrying the electronic tag ID to the background server, the background server searches the optical fiber network clusters classified by the corresponding virtual optical fiber network nodes according to facilities, and returns model data of the corresponding virtual optical fiber network nodes in the optical fiber network clusters to the mobile intelligent terminal.

6. The fiber optic network node management method of claim 5, wherein: and the mobile intelligent terminal receives the data returned by the background server and displays the model, wherein the specific positions of all the virtual optical fiber network nodes correspond to the specific positions of the actual optical fiber network nodes one to one.

7. The fiber optic network node management method of claim 5, wherein: 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, all attribute information of the virtual optical fiber network node is linked, and all the attribute information is displayed through a single interface.

8. The fiber optic network node management method of claim 4, wherein:

the attribute information further includes specific locations of other optical network nodes associated with the corresponding optical network node;

and the background server establishes mapping channels between the corresponding optical fiber network nodes and the associated optical fiber network nodes according to the specific positions of the other optical fiber network nodes, establishes an association model of an optical fiber network cluster in which the virtual optical fiber network nodes at the two ends of the mapping channels are positioned, and distributes channel numbers to each mapping channel.

9. The fiber optic network node management method of claim 8, wherein: and in the model displayed by the mobile intelligent terminal, highlighting the virtual optical fiber network node corresponding to the read electronic tag ID, and displaying all attribute information of the virtual optical fiber network node through a single interface or displaying the association model through the single interface according to selection, wherein a mapping channel is displayed in the association model.

10. The fiber optic network node management method of claim 9, wherein: and when more than one association model is available, selecting the corresponding association model for display through the associated virtual optical fiber network node, wherein the opposite end virtual optical fiber network node in the association model is linked with all the attribute information.

11. The fiber optic network node management method of claims 7 or 9, wherein: when the mobile intelligent terminal displays all the attribute information of the virtual optical network nodes, if the attribute information is modified, the mobile intelligent terminal reports the modified attribute information to the background server, and the background server reclassifies the virtual optical nodes according to the modified attribute information and modifies the model of the optical network cluster in which the virtual optical nodes are reclassified.

12. The fiber optic network node management method of claims 7 or 9, wherein: when the mobile intelligent terminal displays the model of the optical fiber network cluster, if the specific position modification information of the highlighted virtual optical fiber node is received, the mobile intelligent terminal reports the specific position modification information and the electronic tag ID to the background server, and the background server reclassifies the virtual optical node and reconstructs the model according to the specific position modification information and the electronic tag ID.

13. The fiber optic network node management method of any one of claims 1-10, wherein: the optical fiber network node comprises a port, an optical fiber cable, a box and a connector which are used in an optical fiber network; the electronic tag plane is attached to the optical fiber network node or is embedded in the optical fiber network node.

14. A fiber optic network node management system, comprising:

a plurality of electronic tags, each electronic tag having a unique ID and being installed at a fiber optic network node;

the information interaction module is arranged in the mobile intelligent terminal and used for reading the ID of the electronic tag and communicating with the user and the background server;

the management service module is arranged in the background server and used for receiving the electronic tag ID and all attribute information of the corresponding optical fiber network nodes sent by the information interaction module, classifying the electronic tag ID and all attribute information according to different facilities where the optical fiber network nodes are located, and performing sequencing modeling in each class according to specific positions;

the display module is arranged in the mobile intelligent terminal and is used for displaying the specific position and all attributes of the corresponding optical network node in the model;

the receiving and sending module is used for receiving the electronic tag ID and the attribute information of the corresponding optical network node sent by the information interaction module; the system is also used for sending the established model data to the information interaction module;

the modeling module is used for generating a virtual optical network node according to the electronic tag ID and the attribute information of the corresponding optical network node; the attribute information comprises a specific position and a plurality of attributes, and each attribute comprises a plurality of individuals; the modeling module is classified according to the same individual, each type of virtual optical network node generates an optical fiber network cluster, and modeling is carried out according to each optical fiber network cluster.

15. The fiber optic network node management system of claim 14, wherein:

the information interaction module reads the ID of the electronic tag and sends the ID to the management service module, and the management service module returns optical fiber network cluster model data classified by corresponding virtual optical fiber network nodes according to facilities; and the information interaction module receives the model data and calls a display module to display the model.

16. The fiber optic network node management system of claim 14, wherein:

when the attributes are facilities, each facility is an individual, and the modeling module performs distributed sequencing modeling on all virtual optical fiber network nodes in the same optical fiber network cluster according to specific positions;

when the attributes are optical fiber types, operators, plug-in and pull-out states or years, the management service module classifies and generates an optical fiber network cluster according to the same individual, and the modeling module sequences the plurality of virtual optical fiber network nodes in the same optical fiber network cluster according to a preset sequence or directly models without sequencing.

17. The fiber optic network node management system of claim 16, wherein: the information interaction module reads the electronic tag ID, and when receiving a certain input attribute of the corresponding optical network node, sends a request carrying data of the electronic tag ID and the attribute to the management service module; the management service module returns all attribute information of the corresponding virtual optical network node; and the information interaction module calls a display module to display all the attribute information.

18. The fiber optic network node management system of claim 14, wherein: the information interaction module reads the electronic tag ID, and when receiving all input attribute information of the corresponding optical network node, the information interaction module associates the electronic tag ID with the attribute information to obtain associated information and sends the associated information to the management service module; and the management service module classifies and models according to the associated information.

19. The fiber optic network node management system of claim 14, wherein:

the attribute information further includes specific locations of other optical network nodes associated with the corresponding optical network node;

the management service module establishes mapping channels between corresponding optical network nodes and associated optical network nodes according to the specific positions of other optical network nodes, establishes an association model of an optical network cluster in which virtual optical network nodes at two ends of the mapping channels are located, and distributes channel numbers to each mapping channel.

20. The fiber optic network node management system of claim 19, wherein: when the information interaction module receives the query of the association model, the read electronic tag ID and the queried mapping channel are sent to the management service module; and the management service module returns the association model of the cluster where the virtual optical network nodes at the two ends of the mapping channel are located, and the mapping channel is displayed in the association model.

21. The fiber optic network node management system of any one of claims 14-20, wherein: the optical fiber network node comprises a port, an optical fiber cable, a box and a connector which are used in an optical fiber network; the electronic tag plane is attached to the optical fiber network node or is embedded in the optical fiber network node.

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