WO2017118149A1

WO2017118149A1 - Method and apparatus for rapidly collecting fibre interconnection information

Info

Publication number: WO2017118149A1
Application number: PCT/CN2016/102812
Authority: WO
Inventors: 肜云; 齐晓旭
Original assignee: 烽火通信科技股份有限公司
Priority date: 2016-01-07
Filing date: 2016-10-21
Publication date: 2017-07-13
Also published as: CN105634605B; CN105634605A

Abstract

Disclosed are a method and apparatus for rapidly collecting fibre interconnection information, which relate to the field of optical communications. The method comprises the following steps: sorting a device to be tested and a port to be tested; connecting the port to be tested to a transmitting terminal and a receiving terminal respectively; sending the connection relationship to a server; starting the transmitting terminal, and testing each port in sequence; if there is a receiving terminal detecting a signal, sending detection information to the server; after all ports are detected, the server analysing the collected information, so as to obtain an exact connection relationship between the ports and information about an optical cable to which each fibre core belongs. In the present invention, the overall survey and construction time is compressed to be less than 2 hours, thereby improving the resources collection efficiency to a maximization extent, reducing the amount of work during construction, and also avoiding the problem of incorrect resource statistics caused by human factors.

Description

Method and device for quickly collecting optical fiber interconnection information

Technical field

The present invention relates to the field of optical communications, and in particular, to a method and apparatus for quickly collecting information on optical fiber interconnections.

Background technique

The FTTH (Fiber-to-Home) optical cable network based on PON (Passive Optical Network) equipment is an important part of the FTTH network. Its function is for OLT (Optical Line Terminal, An optical transmission channel is provided between the optical line terminal and the ONU (Optical Network Unit), including a fiber optic cable, an optical connector, an optical splitter, and a connection between the operator's equipment room and the user's home. Supporting equipment, etc. The deployment and management of traditional optical distribution network fibers rely on manual methods. When data is entered, it is necessary to manually enter the optical fiber connection to correspond to the back-end database, and the error rate is high. In engineering construction and operation and maintenance, manual search and positioning of fiber connection points or fault points are required. It is difficult to quickly locate fault points during maintenance. The efficiency is low and the sustainability of work is greatly affected.

As shown in FIG. 1 , the existing ring network of a wiring device includes a ring network 1 and a ring network 2, and some nodes may be respectively located in multiple cable rings. For example, the 1# light crosses in FIG. 1 are respectively located in the ring network 1 In the ring network 2, considering the direct-melting core, the core inside the 1# optical box may go to all the wiring devices of the ring network 1 or all the wiring devices of the ring network 2, due to irregularity in the construction process of the optical cable. The accumulation of errors in the splicing operation and the fiber resource recording causes the connection relationship between the various device ports to be confusing.

Intelligent optical wiring network system introduces the world's only electronic label and on-site auxiliary application The software, taking into account the passive properties of the optical distribution network, adds intelligent management functions while maintaining the performance and application range of the conventional optical distribution network system. Optical fiber ID (Identity) management, port status collection, port lookup indicators, PDA (Personal Digital Assistant), and geographic information display, fiber link diagram, and device for the entire network topology The functions of geographic coordinates indicate that the acquisition of network information is more convenient, intuitive and reliable, and the optical fiber can be automatically searched and accurately recorded, thereby achieving efficient deployment of FTTH and fiber fault preparation and positioning, greatly reducing the cost of deployment and operation and maintenance. .

However, prior to the emergence of the intelligent optical wiring system, the existing optical wiring network had excessive manual intervention and chaotic construction process, resulting in low accuracy of current optical fiber resources, corresponding optical path corresponding records and actual site conditions. The direction cannot be one-to-one correspondence. On the one hand, it increases the difficulty of further construction of the Bureau based on existing resources. On the other hand, it brings great challenges to the feasibility of the smart ODN technology for the transformation of the existing network.

Summary of the invention

The object of the present invention is to overcome the deficiencies of the above background art, and to provide a method and a device for quickly collecting optical fiber interconnection information, and compressing the overall survey construction time to within 2 hours, thereby maximizing resource collection efficiency and reducing the efficiency. The workload of the construction process also avoids the problem of inaccurate resource statistics due to human factors.

The present invention provides a method for rapidly collecting information on optical fiber interconnections, including the following steps:

The device to be tested and the port to be tested are arranged, the ports to be tested are respectively connected to the transmitting terminal and the receiving terminal, and the connection relationship is sent to the server; the transmitting terminal is activated, and each port is tested in turn, and if the receiving terminal detects the signal, The detection information is sent to the server; after all ports are detected, the server analyzes and processes the collected information to obtain an accurate connection relationship between the ports and a letter of the optical cable to which each core belongs. interest.

On the basis of the foregoing technical solutions, the transmitting terminal sequentially transmits optical signals to the ports to be tested, and the cores belonging to the same optical cable use the same wavelength, and the signal wavelengths of the cores in different optical cables are different; meanwhile, the receiving terminal measures each in real time. The presence or absence of the optical signal of the test port and the wavelength range, the transmitting terminal and the receiving terminal continuously send relevant information to the server, and the server performs centralized analysis and processing on all the information.

Based on the above technical solution, the device to be tested includes a fiber distribution frame and a cable transfer box.

Based on the foregoing technical solution, the method specifically includes the following steps:

S1. According to the situation of the equipment to be tested and the planning drawings, obtain the basic connection between the devices, determine all the distribution frames and optical junction boxes that need to participate in the test; use the cable detector to connect the nodes. The optical cable is detected, the source end and the sink end of all the optical cables are determined, and the accurate direction of all the optical cables is obtained; the core bundle to which the port to be tested belongs is viewed, the optical cable corresponding to each core bundle is viewed, and the port is divided into different optical cables according to the cable. type;

S2. The transmitting device is configured with a transmitting terminal, and other devices are configured with a receiving terminal, and all the ports of the device to be tested are connected with the ports of the transmitting terminal one by one, and all valid ports of the optical cable host device and the port corresponding to the receiving terminal are simultaneously connected. Connect one by one;

S3. The transmitting terminal and the receiving terminal upload the configured connection relationship to the server.

S4. The transmitting terminal activates the port rotation sending mechanism, and the optical signal is sequentially entered into the wiring device port by the transmitting terminal, and transmitted to other nodes via the optical cable, and optical signals of the same wavelength are used for the cores belonging to the same optical cable; Core, wavelength difference;

S5, all receiving terminals work at the same time, continuously detecting whether the port of each receiving terminal receives an optical signal, if there is a port receiving the optical signal, go to step S6, otherwise go to step S7;

S6, the receiving terminal records the order, time and signal wavelength of the optical signals received by the respective ports, and sends the information to the server, and proceeds to step S7;

S7. The server comprehensively determines the sending and receiving time and sequence of the optical signal, and obtains the source end of each receiving port to connect the core, and at the same time, obtains the port of all the received optical signals according to the wavelength of the optical signal received by the port of each receiving terminal. The number of the cable to which it belongs, and finally the connection relationship between the ports and the cable information table to which the port belongs.

The present invention provides an apparatus for rapidly collecting optical fiber interconnection information, the apparatus comprising at least one transmitting terminal, a plurality of receiving terminals, and a server, wherein:

The transmitting terminal is configured to: generate optical signals of different wavelengths, and transmit optical signals of different wavelengths to a port to be tested; and have a function of communicating with a server, and upload data to the server;

The receiving terminal is configured to: receive an optical signal provided by the transmitting terminal at the other end of the optical fiber connected to the transmitting terminal, and detect and identify an optical signal of a different wavelength; and have a function of communicating with the server, and uploading data to the server;

The server is configured to: collect data uploaded by the transmitting terminal and the receiving terminal in real time, analyze data uploaded by the transmitting terminal and the receiving terminal, and output a detailed connection relationship of the internal core of the tested device.

Based on the above technical solution, the optical signal has a propagation distance greater than 20 km.

On the basis of the above technical solutions, both the transmitting terminal and the receiving terminal comprise a touch screen device.

On the basis of the foregoing technical solutions, each of the transmitting terminals is configured with N ports, N is a positive integer, and N≥1, and supports a single wiring device full test at one time; each receiving The terminal is configured with N detection ports, and supports a single wiring device full test at a time.

Based on the above technical solution, the server includes a software module capable of analyzing and processing information uploaded by the transmitting terminal and the receiving terminal, and supports a function of outputting a report to the analysis result.

On the basis of the foregoing technical solution, the transmitting terminal includes a light source module, an optical switch module, a first control module, a first communication module, and a first switching module, where:

The light source module is configured to: generate optical signals of different wavelengths, and the light source module includes a plurality of light sources supporting different wavelengths;

The optical switch module is configured to: connect the light source module and the switching module;

The first control module is configured to: control other modules inside the transmitting terminal, so that other modules inside the transmitting terminal work together;

The first communication module is configured to: provide a communication channel between the transmitting terminal and the server, and implement data interaction between the transmitting terminal and the server;

The first switching module is configured to complete connection conversion between an outlet of the optical switch module and an external device to be tested, support different fiber port type switching functions, and provide a disk space.

Based on the foregoing technical solution, the first control module includes a first power source, a first communication interface, a light source module control circuit, an optical switch module control circuit, and a first communication module control circuit.

On the basis of the foregoing technical solution, the receiving terminal includes a second switching module, a light detecting module, a second control module, and a second communication module, where:

The second switching module is configured to: complete connection conversion between the receiving terminal and the external device port, support different fiber port type switching functions, and provide disk space;

The light detecting module is configured to: identify the presence or absence of the optical signal, and detect a specific wavelength of the optical signal, and the light detecting module is connected to the optical fiber port of the second switching module, and the light is connected The detection information of the detection module is read by the second control module;

The second control module is configured to: control other modules inside the receiving terminal, so that other modules inside the receiving terminal work together;

The second communication module is configured to: provide a communication channel between the receiving terminal and the server, and implement data interaction between the receiving terminal and the server.

Based on the foregoing technical solution, the second control module includes a second power source, a second communication interface, a light detecting module control circuit, and a second communication module control circuit.

Based on the foregoing technical solution, the server includes a third communication module and a data processing module, where:

The third communication module is configured to: collect data uploaded by the transmitting terminal and the receiving terminal in real time;

The data processing module is configured to: analyze data uploaded by the transmitting terminal and the receiving terminal, and output a detailed connection relationship of the internal core of the tested device.

The advantages of the present invention over the prior art are as follows:

The invention proceeds from the actual situation of the current optical fiber resources, and confirms the accurate content of the optical fiber resources by means of automatic detection of the optical signal, adopts the idea of intelligentization and batchization, and realizes the judgment of the optical fiber direction according to the presence or absence of the optical signal. According to the difference of the wavelength of the optical signal, the judgment of the optical fiber to which the optical fiber belongs is realized, thereby realizing accurate positioning and statistics of the target resource, and the terminal device transmits the measured result to the server through the transmission channel, and finally the server analyzes and obtains the measured optical fiber. The correct direction of resources. The invention compresses the overall survey construction time to less than 2 hours, maximizes the resource collection efficiency, reduces the workload of the construction process, and avoids the problem of inaccurate resource statistics due to human factors.

DRAWINGS

FIG. 1 is a schematic structural view of a ring network of a conventional wiring device.

2 is a flow chart of a method for quickly collecting optical fiber interconnection information in an embodiment of the present invention.

FIG. 3 is a schematic diagram of networking communication of a terminal device according to an embodiment of the present invention.

4 is a schematic view showing the connection of optical fibers in the embodiment of the present invention.

FIG. 5 is a structural block diagram of a transmitting terminal in an embodiment of the present invention.

FIG. 6 is a structural block diagram of a receiving terminal in an embodiment of the present invention.

FIG. 7 is a structural block diagram of a server in an embodiment of the present invention.

detailed description

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

Embodiments of the present invention provide a method for rapidly collecting optical fiber interconnection information, including the following steps:

The device to be tested and the port to be tested are arranged. The device to be tested includes a fiber distribution frame and a cable transfer box, and the ports to be tested are respectively connected to the transmitting terminal and the receiving terminal, and the connection relationship is sent to the server; the transmitting terminal is started, and each port is activated. The test is performed in sequence, and if the receiving terminal detects the signal, the detection information is sent to the server; after all the ports are detected, the server analyzes and processes the collected information to obtain an accurate connection relationship between the ports and the optical cable to which each core belongs. Information.

As shown in FIG. 2, the method for rapidly collecting optical fiber interconnection information in the embodiment of the present invention specifically includes the following steps:

S1. According to the situation of the equipment to be tested and the planning drawings, obtain the basic connection between the devices, determine all the distribution frames and optical junction boxes that need to participate in the test; use the cable detector to connect the nodes. The optical cable is detected to determine the source end and the sink end of all the optical cables, and the accurate direction of all the optical cables is obtained;

View the fiber bundles to which the ports to be tested belong, view the fiber cables corresponding to each core bundle, and classify the ports into different types according to the fiber cables to which they belong. Apply different optical signals to different cables to achieve the purpose of fast classification of fiber resources.

Probing planning: investigate the test equipment and sort out all possible connections Relational equipment; transmitting signals to the optical cables connected between the various devices, drawing the optical cable nodes and the schematic diagram; at the same time, viewing and counting the optical cables of the corresponding optical fibers of each port, and formulating the detection targets and arrangements accordingly;

Optical fiber connection: the fiber port of the device to be tested is respectively connected with the port of the transmitting terminal and the port of the receiving terminal, and the transmitting terminal sequentially transmits optical signals to the ports to be tested, and the cores belonging to the same optical cable use the same wavelength, different optical cables The signal wavelengths of the inner cores are different. At the same time, the receiving terminal measures the presence or absence and the wavelength range of the optical signals of the ports to be tested in real time, and the transmitting terminal and the receiving terminal continuously send relevant information to the server, and the server analyzes and processes all the information in a centralized manner. .

S2. Configure the transmitting terminal for the test device, and configure the receiving terminal for all the devices that may have the optical fiber cable connection relationship with the device to be tested. After the configuration, the terminal and the server network are connected. See Figure 3 for all the ports of the device to be tested. The ports of the transmitting terminal are connected one by one to form a connection relationship as shown in Table 1. For example, the transmitting terminal A1 port in Table 1 is connected to the 1 frame 1 disk 1 port of the 1# optical port to be tested.

Table 1. Connection relationship between ports of the device to be tested and the transmitting terminal port

At the same time, all the effective ports of the optical cable sink device and the end of the corresponding receiving terminal The ports are connected one by one, and the connection relationship as shown in Table 2 is obtained.

Table 2, the connection relationship between the effective port of the optical cable sink device and its corresponding receiving terminal port

S3. The transmitting terminal and the receiving terminal upload all the configured connection relationships to the server.

S4. The transmitting terminal starts the port sending mechanism in turn, and the optical signal is sequentially entered into the wiring device port by the transmitting terminal, and transmitted to other nodes via the optical cable. For the cores belonging to the same optical cable, optical signals of the same wavelength are used; for the cores of different optical cables, the wavelengths are different. See Figure 4, 1# optical crossover 1 and 2 ports of all ports are connected to 1# In the optical cable, the optical signal used by the optical fiber has a wavelength of λ1, and the three disks and four disks are connected to the 2# optical cable, and the optical signal wavelength used is λ2. According to the difference of the wavelength, the optical cable to which the different cores belong can be distinguished.

S6. After the receiving terminal is tested, all the information of the port is counted. Referring to FIG. 4, the receiving terminal connected to the 4# photo-exchange station may detect optical signals from the

optical discs

2, 3, 5, and 6 discs, and the receiving terminal records the order and time of receiving the optical signals by the respective ports. Signal wavelength, and send the information to the server through the upload channel, go to step S7;

S7. The server comprehensively determines the sending and receiving time and sequence of the optical signal, and obtains the source end of each receiving port to connect the core, and at the same time, obtains the port of all the received optical signals according to the wavelength of the optical signal received by the port of each receiving terminal. The number of the optical cable to which it belongs, and finally the connection relationship between the ports as shown in Table 3 and the cable information table to which the port belongs are obtained.

Table 3, the connection relationship of the port receiving the optical signal and the optical cable information table of the port

An embodiment of the present invention further provides an apparatus for rapidly collecting optical fiber interconnection information, where the apparatus includes at least one transmitting terminal, multiple receiving terminals, and a server, where:

The transmitting terminal is configured to: generate optical signals of different wavelengths, the optical signal has a propagation distance greater than 20 km, and emit optical signals of different wavelengths to the port to be tested, and each transmitting terminal is configured with N ports, N is a positive integer, and N≥1, Supports a single distribution device to fully test at a time, and has the function of communicating with the server to upload data to the server;

The receiving terminal is configured to receive an optical signal provided by the transmitting terminal at the other end of the optical fiber connected to the transmitting terminal, and detect and identify optical signals of different wavelengths; each receiving terminal is configured with N detecting ports, and supports one single wiring device at a time. Fully equipped with tests, with the ability to communicate with the server, upload data to the server;

Both the transmitting terminal and the receiving terminal include a touch screen device.

The server is configured to: collect data uploaded by the transmitting terminal and the receiving terminal in real time, analyze data uploaded by the transmitting terminal and the receiving terminal, and output a detailed connection relationship of the internal core of the tested device. The server includes a software module capable of analyzing and processing information uploaded by the transmitting terminal and the receiving terminal, and supports the function of outputting a report to the analysis result.

As shown in FIG. 5, the transmitting terminal includes a light source module, an optical switch module, a first control module, a first communication module, and a first switching module, where:

The light source module is configured to: generate optical signals of different wavelengths, and the light source module comprises a plurality of light sources supporting different wavelengths;

The optical switch module is configured to: connect the light source module and the switch module, and extend the port of the optical switch module, and the transmitting terminal can support more test ports;

The first control module is configured to: control other modules inside the transmitting terminal, so that other modules inside the transmitting terminal work together; the first control module includes a first power source, a first communication interface, a light source module control circuit, an optical switch module control circuit, a first communication module control circuit;

The first switching module is configured to complete connection conversion between the outlet of the optical switch module and the external device to be tested, support different fiber port type switching functions, and provide disk space.

Referring to FIG. 6, the receiving terminal includes a second switching module, a light detecting module, a second control module, and a second communication module, where:

The light detecting module is configured to: identify the presence or absence of the optical signal, and detect the optical signal The body wavelength, the light detecting module is connected to the fiber port of the second switching module, and the detecting information of the light detecting module is read by the second control module;

The second control module is configured to: control other modules inside the receiving terminal, so that other modules in the receiving terminal work together; the second control module includes a second power source, a second communication interface, a light detecting module control circuit, and a second communication module control Circuit

Referring to FIG. 7, the server includes a third communication module and a data processing module, wherein:

A person skilled in the art can make various modifications and variations to the embodiments of the present invention, and such modifications and variations are within the scope of the present invention. .

The contents not described in detail in the specification are prior art known to those skilled in the art.

Claims

A method for rapidly collecting information on optical fiber interconnections, comprising the steps of:

The device to be tested and the port to be tested are arranged, the ports to be tested are respectively connected to the transmitting terminal and the receiving terminal, and the connection relationship is sent to the server; the transmitting terminal is activated, and each port is tested in turn, and if the receiving terminal detects the signal, The detection information is sent to the server; after all ports are detected, the server analyzes and processes the collected information to obtain an accurate connection relationship between the ports and information about the optical cables to which the respective cores belong.
The method for rapidly collecting optical fiber interconnection information according to claim 1, wherein the transmitting terminal sequentially transmits optical signals to the ports to be tested, and the cores belonging to the same optical cable use the same wavelength, and the cores of different optical cables are used. The signal wavelength is different. At the same time, the receiving terminal measures the presence or absence and the wavelength range of the optical signals of each port to be tested in real time. The transmitting terminal and the receiving terminal continuously send relevant information to the server, and the server analyzes and processes all the information in a centralized manner.
The method for rapidly collecting optical fiber interconnection information according to claim 1, wherein the device to be tested comprises a fiber distribution frame and a cable transfer box.
The method for rapidly collecting optical fiber interconnection information according to claim 1, wherein the method specifically comprises the following steps:

S1. According to the situation of the equipment to be tested and the planning drawings, obtain the basic connection between the devices, determine all the distribution frames and optical junction boxes that need to participate in the test; use the cable detector to connect the nodes. The optical cable is detected, the source end and the sink end of all the optical cables are determined, and the accurate direction of all the optical cables is obtained; the core bundle to which the port to be tested belongs is viewed, the optical cable corresponding to each core bundle is viewed, and the port is divided into different optical cables according to the cable. type;

S2. The transmitting device is configured with a transmitting terminal, and other devices are configured with a receiving terminal, and all the ports of the device to be tested are connected with the ports of the transmitting terminal one by one, and all valid ports of the optical cable host device and the port corresponding to the receiving terminal are simultaneously connected. Connect one by one;

S3. The transmitting terminal and the receiving terminal upload the configured connection relationship to the server.

S4. The transmitting terminal activates the port rotation sending mechanism, and the optical signal is sequentially entered into the wiring device port by the transmitting terminal, and transmitted to other nodes via the optical cable, and optical signals of the same wavelength are used for the cores belonging to the same optical cable; Core, wavelength difference;

S5, all receiving terminals work at the same time, continuously detecting whether the port of each receiving terminal receives an optical signal, if there is a port receiving the optical signal, go to step S6, otherwise go to step S7;

S6, the receiving terminal records the order, time and signal wavelength of the optical signals received by the respective ports, and sends the information to the server, and proceeds to step S7;

S7. The server comprehensively determines the sending and receiving time and sequence of the optical signal, and obtains the source end of each receiving port to connect the core, and at the same time, obtains the port of all the received optical signals according to the wavelength of the optical signal received by the port of each receiving terminal. The number of the cable to which it belongs, and finally the connection relationship between the ports and the cable information table to which the port belongs.
An apparatus for quickly collecting information on optical fiber interconnections, characterized in that the apparatus comprises at least one transmitting terminal, a plurality of receiving terminals and a server, wherein:

The transmitting terminal is configured to: generate optical signals of different wavelengths, and transmit optical signals of different wavelengths to a port to be tested; and have a function of communicating with a server, and upload data to the server;

The receiving terminal is configured to: receive the other end of the optical fiber connected to the transmitting terminal Transmitting optical signals provided by the terminal, and detecting and identifying optical signals of different wavelengths; having the function of communicating with the server, and uploading data to the server;

The server is configured to: collect data uploaded by the transmitting terminal and the receiving terminal in real time, analyze data uploaded by the transmitting terminal and the receiving terminal, and output a detailed connection relationship of the internal core of the tested device.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 5, wherein the optical signal has a propagation distance greater than 20 km.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 5, wherein the transmitting terminal and the receiving terminal each comprise a touch screen device.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 5, wherein each of the transmitting terminals is configured with N ports, N is a positive integer, and N≥1, and one single wiring device is fully supported at a time. Test; each receiving terminal is configured with N detection ports, and once supports a single wiring device full test.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 5, wherein the server comprises a software module capable of analyzing and processing information uploaded by the transmitting terminal and the receiving terminal, and supports outputting a report on the analysis result. Features.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 5, wherein the transmitting terminal comprises a light source module, an optical switch module, a first control module, a first communication module, and a first switching module, wherein:

The light source module is configured to: generate optical signals of different wavelengths, and the light source module includes a plurality of light sources supporting different wavelengths;

The optical switch module is configured to: connect the light source module and the switching module;

The first control module is configured to: control other modules inside the transmitting terminal, so that other modules inside the transmitting terminal work together;

The first communication module is configured to: provide communication between the transmitting terminal and the server Channel, to achieve data interaction between the transmitting terminal and the server;

The first switching module is configured to complete connection conversion between an outlet of the optical switch module and an external device to be tested, support different fiber port type switching functions, and provide a disk space.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 10, wherein the first control module comprises a first power supply, a first communication interface, a light source module control circuit, an optical switch module control circuit, and a first communication Module control circuit.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 5, wherein the receiving terminal comprises a second switching module, a light detecting module, a second control module, and a second communication module, wherein:

The second switching module is configured to: complete connection conversion between the receiving terminal and the external device port, support different fiber port type switching functions, and provide disk space;

The light detecting module is configured to: identify the presence or absence of the optical signal, and detect the specific wavelength of the optical signal, the optical detecting module is connected to the optical fiber port of the second switching module, and the detection information of the optical detecting module is used for the second control. Module read;

The second control module is configured to: control other modules inside the receiving terminal, so that other modules inside the receiving terminal work together;

The second communication module is configured to: provide a communication channel between the receiving terminal and the server, and implement data interaction between the receiving terminal and the server.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 12, wherein the second control module comprises a second power supply, a second communication interface, a light detection module control circuit, and a second communication module control circuit.
The apparatus for rapidly collecting optical fiber interconnection information according to claim 5, wherein the server comprises a third communication module and a data processing module, wherein:

The third communication module is configured to: collect the uploading of the transmitting terminal and the receiving terminal in real time. data;

The data processing module is configured to: analyze data uploaded by the transmitting terminal and the receiving terminal, and output a detailed connection relationship of the internal core of the tested device.