JPH05172693A - Monitor devise of star bus type optical fiber line network - Google Patents

Abstract

PURPOSE:To obtain the monitor system of a star bus type optical fiber line network capable of specifying which optical fiber among a plurality of ones trouble is generated in. CONSTITUTION:A monitor device 1 is provided on the office side of a star bus type optical fiber line network 2 and reflecting devices 3 are provided in the line on the respective terminal sides of a plurality of optical fibers 21. The monitor device 1 is equipped with a test signal light generator 10 consisting of a test signal light source 11 and a wavelength sweeping device 12 sweeping the wavelength of test signal light, a light separator 13 separating the reflected return light of the signal light, a photoelectric converter 14 converting the reflected return light to an electric signal and a spectrum analyser 15 analyzing the frequency spectrum of the electric signal. Opposed reflecting surfaces sending back the test signal light to the monitor device is provided in the reflecting device and the interval between the opposed reflecting surfaces is different in all of the individual reflecting devices.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber line network, and more particularly to a starbus type optical fiber line network monitoring system.

[0002]

2. Description of the Related Art A star-bus type optical fiber line network is a line network in which one optical fiber emitted from a station is branched by a star coupler to distribute communication signal light to a large number of subscribers.

In this star-bus type optical fiber line network, as a method of monitoring the occurrence of a failure such as an optical fiber disconnection, a conventional OTDR (Optical Time Domain Reflectomete) is used.
There was a way to use r). For details, refer to the following document by Nakamoto et al., "1990 Autumn Meeting of The Institute of Electronics, Information and Communication Engineers B-692" or I. Sankawa
a, et al., "IEEE Photo. Tech. Lett.
Vol. 2, No. 10, p. 766, 1990 ”.

[0004]

However, OT from the station side
By measuring such a star-bus type optical fiber line network with DR, it is possible to detect that loss increase or disconnection has occurred in the optical fiber beyond the star coupler, but identify which optical fiber after branch has failed There was a problem that I could not.

An object of the present invention is to provide an optical fiber line network monitoring system that solves the above problems.

[0006]

SUMMARY OF THE INVENTION A star-bus type optical fiber line network monitoring system according to the present invention has a monitoring device on the station side of a star-bus type optical fiber line network, and a transparent device in the far end line on each terminal side. And reflectors each having the above are provided. The monitoring device includes a test signal light generating means for emitting a test signal light whose wavelength changes, a photoelectric conversion means for converting an optical signal into an electric signal, and a test signal light from the signal light generating means for a star-bus type optical fiber line. An optical splitting / coupling means for extracting light coming from the terminal side of the star-bus type optical fiber line network while being incident on the network and giving it to the photoelectric conversion means, and a means for analyzing the frequency spectrum of the output electric signal of the photoelectric conversion means are provided. I have it. The reflector has a reflectance of 1 facing each other.
It has a structure in which the following two reflecting surfaces are inserted in the line, and the distance between the two reflecting surfaces in the reflector is different for each terminal.

The reflecting surfaces of the above-mentioned plurality of reflectors have a small reflectance with respect to the wavelength of the ordinary communication signal light,
Moreover, it is desirable that a dielectric multilayer film having a large reflectance for the wavelength of the test signal light be coated.

[0008]

When the test signal light of varying wavelength is sent from the test signal light generating means to the star-bus type optical fiber line network through the optical separating / coupling means, the test signal light reaches the respective reflectors on the terminal side. .. Therefore, the test signal light incident on the reflector is multiply reflected by the opposing reflecting surface. Amplitude modulation according to the reflection surface interval is applied to the test signal light that has been multi-reflected,
Part of each of the reflectors travels backward in the star-bus type optical fiber line network as reflected return light. These reflected return lights are converted into electric signals by photoelectric conversion means through the light separating / coupling means in the monitoring device. This electric signal reaches the spectrum analyzer and the frequency spectrum is analyzed.

The above-mentioned opposing reflecting surfaces are provided with a predetermined spacing, and this spacing has a different value for each individual reflector. Here, the distance between two facing surfaces is d, the initial wavelength of the test signal light is λ ₀ , and the sweep speed of the wavelength is α.
Then, the modulation frequency f of the reflected return light is given by f = dα / λ ₀ ² . Therefore, even if λ ₀ and α for each reflector have the same value, if the value of d is different, the modulation frequency of the reflected return light is different. Therefore, the state of the reflected return light can be detected for each terminal (for each reflector) by analyzing the frequency spectrum.

[0010]

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

FIG. 1 shows a star-bus type optical fiber line network monitoring system according to an embodiment. A star-bus type optical fiber line network (hereinafter referred to as an optical fiber line network) 2 to be monitored has a star coupler 6 between a station side and a subscriber side, and a signal sent from the station side. Light is
It is sent via the star coupler 6 to a plurality of optical fibers 21 which are branched, and each is transmitted to the subscriber side.

The monitoring system of this embodiment provided for such an optical fiber line network 2 sends the test signal light to the optical fiber line network 2 and reflects the reflected light from the reflector 3 described later. It has a monitoring device 1 for analysis, and a plurality of reflectors 3 connected to the subscriber side of a plurality of optical fibers 21 included in the optical fiber line network 2 and respectively reflecting test signal light.

The monitoring device 1 has a test signal generator 10 for transmitting a test signal light having a variable wavelength. The test signal generator 10 includes a test signal light source 11 and a test signal emitted from the test signal light source 11. Wavelength sweeping device 1 for sweeping the wavelength of signal light 1
It consists of 2. Here, as the wavelength tunable test signal light source 11, a DFB (distributed feedback type) semiconductor laser with a grating added as an external resonator is used. In this DFB semiconductor laser, the oscillation wavelength can be swept by mechanically driving the tilt of the grating by the wavelength sweeping device 11. Furthermore, this monitoring device 1 is an optical demultiplexer (optical fiber coupler) that separates the test signal light emitted from the test signal generator 10 described above from the reflected return light from the reflector 3 installed on the subscriber side. )
13, a photoelectric converter (O / E converter) 14 that detects the reflected return light and converts it into an electric signal, and a spectrum analyzer 15 that analyzes the frequency spectrum of the electric signal.

Next, the reflector 3 will be described with reference to FIG. As shown in the figure, an optical fiber 21 branched from a star coupler is inserted into one end of the reflector 3, and a rod lens 51 is connected to the tip thereof to reduce insertion loss. An optical fiber 22 leading to the subscriber is inserted from the other end of the reflector 3.
Like the optical fiber 21, at the tip of the inside of the reflector 3 of
The rod lens 52 is connected. The end surfaces of the rod lenses 51 and 52 are opposite reflection surfaces 31 and 32, respectively.
Is formed. Rod lens 5 used here
Nos. 1 and 52 are adjusted so that the signal light is a substantially parallel beam, and are aligned so that the parallel beam is incident most efficiently. The opposing reflecting surfaces 31 and 32 are provided so as to be maintained at a predetermined distance d, and the distance d is determined by the individual reflectors 3.
It takes different values depending on. Next, the operation of the monitoring system of this embodiment configured as described above will be described. When the test signal light whose wavelength changes at a constant speed is emitted from the test signal generator 10, the test signal light is sent to the optical fiber line network 2 via the optical demultiplexer 13. Then, this test signal light is distributed to each terminal by the star coupler 6 and reaches all the reflectors 3. In each reflector 3, the test signal light is multiple-reflected by the opposing reflection surfaces 31 and 32, and a part of it travels backward in the optical fiber line network 2 as reflected return light and is sent to the monitoring device 1. In the monitoring device 1, the reflected return light is transmitted to the photoelectric converter 14 via the optical demultiplexer 13.
After being converted into an electric signal, it further reaches the spectrum analyzer 15 and its frequency spectrum is analyzed.

The reflectance R of the light passing through the opposite reflecting surfaces 31 and 32 in the reflector 3 is given by the following equation in consideration of multiple reflection.

[0016]

[Equation 1]

In the above mathematical expression 1, R ₀ is the reflectance of a single surface, λ is the wavelength of light, and d is the distance between opposed surfaces. R
_{If 0} is a value that is extremely smaller than 1, it may be approximated as follows.

[0018]

[Equation 2]

In this embodiment, it is considered that the wavelength λ of the test signal light is changed with time. For example, consider a case where the wavelength is swept from the initial wavelength λ _{0 at a} constant speed α such that λ = λ ₀ + αt with respect to time t. Assuming that αt is infinitely smaller than λ ₀ , the reflectance R is

[0020]

[Equation 3]

It can be seen that, even if the incident light is CW (continuous oscillation) light, the reflected light undergoes amplitude modulation. Here, as described above, the modulation frequency f of the reflected light is given by f = dα / λ ₀ ² . Therefore, even if λ ₀ and α are the same,
When d is different, the modulation frequency of reflected light is different. Different modulation frequencies can be obtained depending on the value of d.

The following are examples of numerical values when the distance d between the opposite reflecting surfaces is changed.

Λ ₀ = 1.55 μm, α = 10 nm / se
In the case of c, if d = 20 mm, f = 83.2 Hz, and if d = 30 mm, f = 124.9 Hz.

As described above, different modulation frequencies can be obtained by changing the distance d between the opposing reflecting surfaces 31, 32 of each reflector 3.

From the above, the distance d between the opposing reflecting surfaces 31, 32 is d.
The reflected light returned simultaneously from a plurality of reflectors 3 which are set so as to be different from each other is once converted into an electric signal by the photoelectric converter 14, and the modulation frequency component is analyzed by the spectrum analyzer 15 to determine which reflection It is possible to identify whether the reflected light has returned from the vessel or not, and it is possible to identify which optical fiber has failed.

FIG. 3 schematically shows a signal waveform observed on the spectrum analyzer 15 of the above-mentioned monitoring device 1. For example, in the optical fiber 21 that is branched into eight by the star coupler 6 (shown in FIG. 1), if the distances d between the opposing reflecting surfaces of the reflectors 3 installed in the respective fibers are set to be different, the corresponding values will be 8 Individual frequency components are observed. FIG. 3A shows a signal waveform when all eight branched optical fibers 21 are normal. If a break occurs in one of the optical fibers and the reflected light does not return, only one frequency component corresponding to it cannot be observed (arrow (b) in the figure), so a failure occurs in that particular fiber. You can see that Further, by accurately measuring the amplitude of each frequency component and continuing to monitor it, it is possible to detect the change in transmission loss of each fiber from the change in the amplitude.

By the way, since the reflector 3 passes not only the test signal light but also the communication signal light, it is not preferable that the communication signal light is largely reflected. Further, it is advantageous in measurement that the reflectance of the test signal light is as large as possible. Therefore, the dielectric multilayer coatings 41 and 42 having a low reflectance for communication signal light (for example, wavelength 1.3 μm) and a high reflectance for test signal light (for example, wavelength 1.55 μm). Is preferably applied to both facing surfaces 31 and 32. With this structure, the communication signal light is transmitted through the counter reflection surface 31,
It becomes easy to pass through 32, and the test signal light becomes easy to reflect on the counter reflection surface.

In the present embodiment, description of the connection relationship between the original communication transmission device on the station side and the optical fiber line network is omitted. However, for example, when the test signal light wavelength is different from the communication signal light wavelength. Can combine the communication signal light from the communication transmission device and the test signal light from the monitoring device with an optical multiplexer, and then send out to the optical fiber line network to be measured.

[0029]

As described above in detail, according to the present invention, the test signal light transmitted from the station side is multiply reflected by the opposing reflection surface in the reflector provided in the line on each terminal side. Then, the amplitude modulation is applied according to the distance between the reflecting surfaces. A part of the light travels backward in the optical fiber line as reflected return light, and the spectrum spectrum in the monitoring device analyzes the frequency spectrum.

Therefore, when a failure occurs in a plurality of optical fibers after branching of the star-bus type optical fiber line network, the failed optical fiber is specified by comparing the analyzed frequency spectra. can do. Further, by accurately measuring the amplitude of each frequency component and continuing to monitor it, it is possible to detect the change in the transmission loss of each fiber from the change in the amplitude. Therefore, it is possible to effectively monitor the optical fiber line network.

[Brief description of drawings]

FIG. 1 is a diagram showing an optical fiber line network monitoring system according to the present invention.

FIG. 2 is a diagram showing a structure of a reflector used in the present invention.

FIG. 3 is a waveform diagram observed in the monitoring method of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Monitoring device 10 ... Test signal generator 11 ... Test signal light source 12 ... Wavelength sweep device 14 ... Photoelectric converter 15 ... Spectrum analyzer 2 ... Optical fiber line network 21, 22 ... Optical fiber 3 ... Reflector 31, 32 ... Opposite Reflective surface 41, 42 ... Dielectric multilayer coating 51, 52 ... Rod lens 6 ... Star coupler

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location H04L 12/44

Claims (2)

[Claims] 1. A monitoring device is provided on a station side of a star-bus type optical fiber line network, and a transparent reflector is provided in a far end line of each terminal side, and the monitoring device is a test signal whose wavelength changes. A test signal light generating means for emitting light, a photoelectric converting means for converting an optical signal into an electric signal, and a test signal light from the signal light generating means for entering the star bus type optical fiber line network and a star bus type An optical separation / coupling means for extracting the light coming from the terminal side of the optical fiber line network and giving it to the photoelectric conversion means, and means for analyzing the frequency spectrum of the output electric signal of the photoelectric conversion means, and the reflector, A star bus having a structure in which two reflecting surfaces having a reflectance of less than 1 facing each other are inserted in a line, and a distance between the two reflecting surfaces in the reflector is different for each terminal. Type Optical fiber network monitoring system. 2. A dielectric multilayer film having a small reflectance for a normal communication signal light wavelength and a large reflectance for a test signal light wavelength is coated on the reflecting surface of each of the plurality of reflectors. Item 2. A star-bus type optical fiber line network monitoring system according to Item 1.