RU2723467C1 - System for monitoring fiber-optic communication lines - Google Patents

Abstract

FIELD: communication equipment.

SUBSTANCE: system for monitoring fiber-optic communication lines comprises at least one optical switching panel which has adapter adapters, to at least one of which is connected an input connector of a corresponding first Y-shaped asymmetric optical splitter, first output connector of which is connected to first output connector of corresponding second Y-shaped asymmetric optical splitter, input connector of which is intended to connect end of fiber-optic communication line, second output connectors of each Y-shaped asymmetric optical splitter are connected to inputs of corresponding photodetectors, output of each of which is connected to appropriate input of corresponding microcontroller, which output is connected to corresponding input of processing and information transfer unit, which output is output of monitoring system of fiber-optic communication lines.

EFFECT: broader functional capabilities and high reliability of information on occupancy of ports of switching panels of fiber-optic communication lines.

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Description

The invention relates primarily to communication technology, in particular, to the equipment of cable systems and can be used to identify some parameters of the optical signal in optical waveguides. Based on these parameters, a system for monitoring the status of ports of fiber-optic cable systems is formed.

Known systems for monitoring cable connections in fiber-optic communication lines, such as a solution from FiberWatch, NQMSfiber, ONMSi, etc. Such systems are implemented using similar operating principles — fiber testing is carried out using an optical pulse reflectometer, which diagnoses the state of the fiber by light backscattering waves when probing pulses are introduced into the fiber. All of these monitoring systems allow you to measure, process, analyze and compare current reflectograms with a reference. Some systems have the ability to implement functions for automatically detecting, localizing and displaying on the geographic map the resulting damage to the fiber optic communication line (FOCL). In addition, some systems have functions that automatically detect and localize any discontinuities in the optical fiber, whether it is a break, fiber degradation or bending (for example, unauthorized connection on a fiber bend) and indicate the type of malfunction detected. The differences between the systems are in the set of monitoring functions, as well as in the composition of the remote testing units and the applied software (including operating systems and databases). There are no significant differences in the principles of monitoring active fibers. So, for example, there are two types of monitoring of active fibers: active - using spectral multiplexers (Wavelength Division Multiplexer - WDM), passive - indirectly, according to the state of "dark" fibers. Despite the wide functionality of such systems, they also have drawbacks: it is not always possible to use “dark” / free fiber to monitor the condition of the line due to the limited capacity of the cable system, the introduction of spectral multiplexers may not be possible due to information security restrictions. In addition, the implementation of the described systems may require substantial modernization of the existing fiber-optic cable system, and the cost of such systems can be several million rubles, even for a compact structured cable system (SCS).

The closest analogue of the claimed system is a monitoring system for optical cable connections (RF patent No. 2667711 04/04/2017 priority, “Monitoring system for optical cable connections”, author: Boris Alekseevich Khozyainov, IPC: H04L 12/26, G01R 31/00, H04B 10 / 07, published September 24, 2018 Bull. No. 27). The description of this invention indicates that for monitoring optical cable connections, the patch panel port is equipped with a sensor that senses spurious electromagnetic radiation that occurs near the optical fiber due to the transmission of optical signals (in particular, signals for establishing a network connection) through the fiber. Temporarily change the signal to establish a network connection and, comparing the time of the signal change to establish the network connection and the time of the sensor signal change, identify the port of the patch panel where the network device that transmits the signal to establish the network connection is connected.

The disadvantage of this system is the inability to determine the presence of an optical signal in the waveguide on the side remote from the source, because spurious electromagnetic radiation will be extremely small. In addition, this system does not determine the direction of the optical signal, as well as its power (or deviation from threshold power values).

The technical problem is the creation of a monitoring system for optical cable connections, capable of determining the presence / absence of an optical signal in a particular optical waveguide, including on the remote side from the source, as well as its direction and power (or deviation from threshold power values), provided that the costs the implementation of such a system will be minimal and no significant modernization of the existing cable system will be required.

The technical results to which the invention is directed are the expansion of functionality, increasing the reliability of information on the employment of ports of patch panels of fiber-optic communication lines.

These technical results are achieved by the fact that the monitoring system of fiber-optic communication lines contains at least one optical patch panel, which contains adapter adapters, to at least one of which is connected to the input connector of the corresponding first Y-shaped asymmetric optical splitter the first output connector of which is connected to the first output connector of the corresponding second Y-shaped asymmetric optical splitter, the input connector of which is designed to connect the end of the fiber-optic communication lines, the second output connectors of each Y-shaped asymmetric optical splitter are connected to the inputs of the respective photodetectors, the output of each of which is connected to the corresponding input of the corresponding microcontroller, the output of which is connected to the corresponding input of the information processing and transmission unit, the output of which is the output of the monitoring system of fiber-optic communication lines.

Functionality enhancements are:

- the ability to determine the presence of an optical signal in the waveguide, including on the side remote from the source;

- the ability to determine the direction of the optical signal in a specific port of the optical patch panel;

- the ability to identify the power of the optical signal (or deviations from threshold power values).

The expansion of functionality is achieved by the use of the first and second Y-shaped asymmetric optical splitters, which are mounted in the optical fiber gap using detachable connections in the optical patch panel, and connected to the corresponding inputs of the microcontroller, in which the received information is processed and transmitted to a personal computer ( PC) of an operating service employee who converts the information received from the microcontroller on the presence and direction of the optical signal in the port of the optical patch panel, as well as on its power (or deviation from the threshold power values) into a convenient readable format. These signs together increase the reliability of the information on the employment of ports of patch panels of fiber-optic communication lines.

The use of the inventive system minimizes the cost of implementing a monitoring system for fiber-optic communication lines with the necessary functionality, while more expensive systems have excess functionality and in place have a number of disadvantages: the need to use "dark" / free fiber, lack the possibility of determining the direction of the signal, the need to modernize the existing cable system, restrictions on information security, etc.

In FIG. Figure 1 shows a diagram of an embodiment of a monitoring system for fiber-optic communication lines using an example of one patch panel and shows the installation of optical splitters. In FIG. 2 shows a diagram of the operation of a monitoring system for fiber-optic communication lines.

The monitoring system of fiber-optic communication lines (Fig. 1) includes an optical patch panel 1, adapter adapters 2 ₁ , ..., 2 _k , the first Y-shaped asymmetric optical splitter 3, the second Y-shaped asymmetric optical splitter 4, the first 5 and second 6 photodetectors.

At least one of the adapters 2 ₁ , ..., 2k (for example, the adapter 20 is connected to the input connector of the first Y-shaped unbalanced optical splitter 3, the first output connector (90%) of which is connected to the first output connector (90% ) of the second optical splitter 4. The input connector of the second Y-shaped unbalanced optical splitter 4 is connected to the pigtail connector 7 (patch cord) to which the end of the optical waveguide is secured.The second output connector (10%) of the first Y-shaped asymmetric optical the splitter 3 is connected to the input of the photodetector 5. The second output connector (10%) of the second Y-shaped asymmetric optical splitter 4 is connected to the input of the photodetector 6. The output of each photodetector 5 (6) is connected to the corresponding input of the microcontroller 8 (not shown in Fig. 1, see Fig. 2), the output of which is connected to the corresponding input of the information processing and transmission unit 9 (Fig. 2), whose output is the output of the system Monitoring fiber-optic communication lines.

Each involved port of each optical patch panel 1 represents the end of a fiber optic communication line, made in the form of standard optical connectors (SC, LC, SC, etc.), placed in a standard case in the form of a box or panel.

The patch panel 1 is designed to perform switching cable lines.

Each adapter adapter 2 _{k of the} optical patch panel 1 is a passive connector, the design of which allows you to combine the waveguides of the optical patch cord and pigtail so that the optical signal passes through them with minimal loss.

Y-shaped asymmetric optical splitters 3, 4 are a passive device that separates the flow of light energy in various proportions (with different power), transmitted via optical fiber. In a particular case, a splitter is used that divides the optical signal into two parts: 90% on one branch, 10% on the other branch. The input connector of the first Y-shaped unbalanced optical splitter 3 is designed to connect to the corresponding adapter 2 _k . The input connector of the second Y-shaped asymmetric optical splitter is designed to connect the end of the fiber optic communication lines (pigtail).

Pig tail 7 (English Pig tail) is a piece of cable terminated on one side by a connector of a certain type. The optical pigtail is connected to the cable fiber by welding.

Photodetector 5 (6) is designed to identify the optical signal in the waveguide, as well as its power, taking into account the wavelengths used in SCS (1310, 1550 nm for single-mode SCS elements and 850 nm for multimode).

For each patch panel 1 (or a group of patch panels, depending on the number of ports used), the corresponding microcontroller 8 is installed (Fig. 2), which generates information for transmission to the PC of an operational service employee. Microcontroller 8 is designed to convert an analog signal from a photodetector to a digital one, as well as to generate and transmit information about the optical signal power values in waveguides to a processing unit, the interface of which interacts with one of the interfaces of an employee PC 10 (in the particular case of RS232). Information from the microcontrollers 8 ₁ , ..., 8 _k is transmitted to the information processing and transmission unit 9, which is connected directly to the PC 10 of the operational service employee.

The monitoring system of fiber optic communication lines operates as follows.

Each photodetector 5 (6) is responsible for identifying a certain parameter corresponding to the waveguide of the fiber-optic communication lines: signal presence / direction / quality.

Each output of the photodetector 5 (6) is associated with a microcontroller 8 with a specific port on the patch panel (each pin on a separate port). In addition, each output from a pair of photodetectors 5 (6) is responsible for identifying the direction of the signal in the waveguide of the fiber-optic communication lines. So, when a signal passes through a waveguide in a certain direction, an optical signal is identified only on one of the photodetectors (from a pair).

When identifying the presence of a signal from one of the photodetectors 5 (6), the microcontroller 8 converts the received information into a digital form (an approximate numerical value of the power) and compares the obtained value with predetermined threshold values. If the signal power in the waveguide is higher than the threshold value, then the microcontroller 8 generates information about the direction of the signal in the line, and also that the line is busy and the signal quality is normal. If the signal power in the waveguide is below the threshold value, then the microcontroller generates information about the direction of the signal in the line, and also that the line is busy and the signal quality is below normal, which may indicate damage to the line.

If the microcontroller 8 could not identify the presence of an optical signal on any of the pair of photodetectors, then it generates information that the line is free.

After the microcontroller 8 has generated information about the signals coming from the photodetectors 5, 6 (availability, direction, quality), it transmits it to the processing unit, where information from the other microcontrollers is accumulated. Next, the information processing and transmission unit 9 transmits the total information to the employee PC 10 for use in the work.

Claims (1)

A system for monitoring fiber-optic communication lines containing at least one optical patch panel that contains adapter adapters, to at least one of which is connected an input connector of the corresponding first Y-shaped asymmetric optical splitter, the first output connector of which is connected to the first output connector the corresponding second Y-shaped asymmetric optical splitter, the input connector of which is used to connect the end of the fiber optic communication line, the second output connectors of each Y-shaped asymmetric optical splitter are connected to the inputs of the respective photodetectors, the output of each of which is connected to the corresponding input of the corresponding microcontroller, the output which is connected to the corresponding input of the information processing and transmission unit, the output of which is the output of the monitoring system of fiber-optic communication lines.

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