JP2000134153A - Pds optical line supervisory system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a PDS optical line supervisory system capable of specifying an abnormity point in a plurality of subscriber side transmission lines with one testing device. SOLUTION: A test pulse light from an OTDR 2 is given to a 1:n optical multiplexer/demultiplexer 5, where the light is demultiplexed into (n) signals, the signals are sent to each subscriber home through an optical fiber grating 6. In the transmission characteristic of the optical fiber grating 6, the light of band other than that of the test pulse light is passed, and the band of the test pulse light is blocked. However, only a light with wavelength bands of λ1, λ2,..., λn different from each subscriber is transmitted. In this characteristic, the test pulse light transmitted through the optical fiber grating 6 is scattered in an optical transmission line 7 or part of the light is returned in a direction of an in-station device 9 through reflection at a fiber connecting point or an abnormity point. The returned light is analyzed to locate at which point of which path of the optical transmission lines 7, a fault takes place.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a PDS (Passive
Double Star) Optical line monitoring system, especially OTD
The present invention relates to a PDS optical line monitoring system configured with R.

[0002]

2. Description of the Related Art Conventionally, PDS optical line monitoring systems generally use ONUs in B-ISDN (Broadband ISDN).
In the connection between the (optical network terminating device) and the center side, one optical fiber is divided into, for example, 16 via the optical star coupler of the branching device, so that one-to-many communication is possible.

[0003] As a second conventional example of the technical field similar to the present invention, "Optical communication system" disclosed in Japanese Patent Application Laid-Open No. Hei 9-135206.
There is. In this conventional example, optical fiber gratings D having different Bragg wavelengths and reflection efficiencies are connected in front of optical communication terminals C for optical subscribers. According to this configuration, it is possible to specify individual fault points in the optical fiber line behind the optical splitter.

As another conventional example 3 similar to the present invention, there is an "optical line monitoring method" disclosed in Japanese Patent Laid-Open No. 6-179661. In this conventional example, in an optical communication system including a large number of optical fiber lines, it is possible to search for a fault point in a plurality of optical fiber lines. Conventional example 2
In the method (1), the above-described one-to-many communication is enabled by using a branch coupler.

[0005]

However, in the optical communication system having the above-mentioned conventional PDS configuration, the OT
When an attempt is made to monitor an abnormality in an optical transmission line using a DR (optical fiber fault point detector), one test apparatus cannot identify which line on the subscriber side has an abnormality.
Therefore, it is necessary to individually monitor each subscriber line in order to identify which transmission line on the subscriber side has an abnormality.

In the conventional example 2, as described in paragraph 0006 of the publication of the conventional example, the OTDR
In order to check the fault point of this system, light from λ to λN is sequentially incident from the optical communication terminal A in the station, and the intensity of the reflected light is measured by OTDR as a function of time. That is, light of λN is incident from the optical communication terminal A, and the light intensity of the reflected light is measured as a function of time, and the state of the N-th optical fiber line L1 and the optical fiber line L2 can be examined. Thus, the procedure is a serialization of the individual measurements of the individual subscriber lines.

Further, in the above-mentioned conventional example 3, the inspection light reflected from each of the plurality of optical fiber lines is reflected by the optical fiber line.
Light is sequentially received by the TDR, and each fiber line is monitored.

[0008] The present invention provides a PD capable of simultaneously specifying an abnormal point in a plurality of subscriber-side transmission paths by one test apparatus.
An object is to provide an S optical line monitoring system.

[0009]

In order to achieve the above object, a PDS optical line monitoring system according to the present invention transmits a predetermined main signal and a test pulse light having a wavelength different from that of the main signal. An indoor apparatus for analyzing the scattered and returned test light, and n-branch output of one input light for output 1: n
It is characterized by comprising an optical coupling / branching device and an optical fiber grating having a grating in a fiber and transmitting and blocking light of a specific wavelength.

The transmission characteristics of the optical fiber grating are such that light in a band other than the test pulse light is transmitted,
The band of the test pulse light is blocked. However, in the stop band, different wavelengths λ1, λ2,.
It is preferable that only n is transmitted.

Further, the indoor unit transmits an optical transmitting / receiving device for transmitting / receiving a predetermined main signal and a test pulse light,
In addition, it may be configured to include an OTDR that analyzes test light and a WDM that combines two types of light having different wavelengths.

The above PDS optical line monitoring system is connected to an optical fiber grating by an optical transmission line, converts an intra-office signal into an optical signal and sends it out, and converts an optical signal from the subscriber side into an intra-office signal. It is preferable to further include an optical transceiver for conversion.

Also, a test pulse light having a wavelength different from that of the main signal light and having a certain wavelength band is transmitted from the OTDR. The test pulse light is multiplexed with the main signal by WDM and is transmitted to an optical transmission line. , And n-branched by a 1: n optical coupling / branching device, and then sent to an optical fiber grating.

Furthermore, by analyzing the light that is reflected and scattered while the test light is propagating through the optical transmission line and returns to the OTDR, it is possible to determine at which point on the optical transmission line an abnormality has occurred. Identification should be possible.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of a PDS optical line monitoring system according to the present invention will be described in detail with reference to the accompanying drawings. 1 to 7, there is shown one embodiment of the PDS optical line monitoring system of the present invention.

FIG. 1 shows a PDS optical line monitoring system according to the present embodiment, which includes an in-station device 9, a 1: n optical multiplexer / demultiplexer 5, an optical fiber grating 6, and a customer premises device 10. These devices are connected by optical transmission lines 4 and 7. The intra-station device 9 is further subdivided and includes the optical transmitting / receiving device 1, the OTDR 2, and the WDM 3. The subscriber premises apparatus 10 is composed of a plurality of optical transmission / reception apparatuses 8,..., 8, and each optical transmission / reception apparatus 8 is connected to an optical fiber grating 6 by an optical transmission path 7.
Connected to The plurality of optical fiber gratings 6,..., 6 corresponding to the plurality of optical transmission / reception devices 8,.
Are collectively connected to one 1: n optical combining / branching device 5.

Referring to FIG. 1, an optical transmitting / receiving apparatus 1 has a function of converting an intra-office signal into an optical signal and transmitting the same, and converting an optical signal from a subscriber side into an intra-office signal. OTDR (Op
The tical time domain reflectometer 2 has a function of transmitting a test pulse light having a wavelength different from that of the main signal, and a function of analyzing the reflected and scattered test light. Note that this OTDR can also be configured using a wavelength tunable filter, a separator, and the like.

WDM (Wavelength Division Multiplex)
ng) 3 has a function of multiplexing two types of light having different wavelengths and a function of separating light containing two types of wavelengths into two for each wavelength.

The optical transmission lines 4 and 7 are composed of optical fibers and have a function of transmitting an optical signal. The 1: n optical multiplexing / branching device 5 has a function of n-branching one input light and a function of multiplexing n input lights into one. The optical fiber grating 6 has a function of having a grating in the fiber and transmitting and blocking light of a specific wavelength. The optical transmission / reception device 8 has a function of converting a signal in the subscriber's house into light and sending it to the station side, and a function of converting an optical signal from the station side into a signal in the subscriber's house.

A method generally used as a method of forming a fiber grating utilizes a photo-induced change in refractive index. The light-induced refractive index change is a phenomenon in which the refractive index changes when strong ultraviolet light is mainly applied to a germanium dioxide (GeO ₂ ) -doped fiber.
By utilizing this phenomenon and irradiating the laser with interference on the fiber, the refractive index changes periodically, and a refractive index diffraction grating is formed in the fiber.

FIG. 2 shows a configuration example of a fiber grating forming method using a phase mask (phase grating). In this method, the laser light 23 transmitted through the phase mask 21
Interferes and irradiates the fiber 22. By changing the structure (period and phase) of the phase mask 21 and the wavelength and intensity of the laser beam 23 during irradiation, fiber gratings having various characteristics are formed. In the case of the present embodiment, a phase mask having a configuration in which the phase is shifted by π in the middle of the phase mask 21 is used. Thus, a fiber grating having the characteristics shown in FIGS. 3 to 5 can be formed.

As a first method relating to the wavelength separation method,
There is a method of using a narrow-band tunable laser as a light source of the OTDR. For example, if the wavelength of the light source is adjusted to the transmission wavelength of the fiber grating on the line to be measured, the characteristics of the line to be measured can be seen.

As a second method relating to the wavelength separation method,
By putting a spectroscope or the like in front of the light receiving section of the OTDR and adjusting the wavelength to the transmission wavelength of the fiber grating on the line to be measured, the characteristics of the line to be measured can be seen.

(Description of Operation) Next, the operation of the apparatus shown in FIG. 1 will be described. The optical main signal transmitted from the optical transceiver 1 is transmitted to the optical transmission line 4 via the WDM 3. 1: n
The light is branched into n light by the optical coupling / branching device 5, passes through the optical fiber grating 6, and is transmitted to each subscriber's house. Transmission in the opposite direction is also performed.

On the other hand, a test pulse light having a wavelength band different from that of the main signal light and having a certain wavelength band is transmitted from the OTDR 2. The test pulse light is multiplexed with the main signal by the WDM 3 and transmitted to the optical transmission line 4. Then, it is n-branched by the 1: n optical combining / branching device 5 and sent to the optical fiber grating 6.

As shown in FIGS. 3, 4 and 5, the transmission characteristics of the optical fiber grating 6 are such that light in a band other than the test pulse light is transmitted and the band of the test pulse light is blocked. However, only the different wavelengths λ1, λ2,..., Λn for each subscriber are transmitted in the stop band. In this characteristic, a part of the test pulse light transmitted through the optical fiber grating 6 is returned to the local station 9 due to scattering at the optical transmission line 7 or reflection at a connection point or an abnormal point of the fiber. That is, the scattered / reflected light passes through the optical fiber grating 6 again, and
And propagates through the optical transmission line 4 to the ODM through the WDM 3.
Return to TDR2.

The test pulse light returned to OTDR2 is
As shown in FIGS. 6 and 7, separation is performed for each wavelength, and a time change is observed. FIG. 6 is an observation characteristic diagram showing the relationship between the wavelength λ1 light intensity and the distance. FIG. 7 is an observation characteristic diagram showing the relationship between the light intensity of the wavelength λ2 and the distance. In these characteristic diagrams, the light intensity observation at the wavelength λ1 in FIG. 6 is normal. However, an abnormality has occurred in the light intensity observation of λ2 in FIG. Thereby, the connection point or the abnormal point of the fiber of the optical transmission line 7 can be specified.

According to the above embodiment, in the optical communication system having the PDS configuration, an abnormal point in the transmission line on the subscriber side can be specified by one test apparatus on the station side. That is,
The PDS optical line monitoring system according to the present invention enables monitoring of an optical transmission line from a branch point to a subscriber's house in an optical communication system having a PDS configuration. For example, in FIG. 1, the test pulse light from the OTDR 2 is branched into n by a 1: n optical multiplexer / demultiplexer 5 and transmitted to each subscriber's house through an optical fiber grating 6. The test light is reflected and scattered while propagating through the optical transmission line 7, and by analyzing the light returning to the OTDR 2, it is specified which path of the optical transmission line 7 has an abnormality at which point.

The above embodiment is an example of a preferred embodiment of the present invention. However, the present invention is not limited to this, and various modifications can be made without departing from the scope of the present invention.

[0030]

As is clear from the above description, the PDS optical line monitoring system of the present invention branches one input light into n branches, has a grating in the optical fiber, and transmits and blocks light of a specific wavelength. Has characteristics. Based on this characteristic,
A predetermined main signal and a test pulse light having a wavelength different from that of the main signal are transmitted, and the returned and reflected test light is analyzed. Therefore, according to this analysis, it is possible to specify an abnormal point of a line in a plurality of subscriber-side transmission lines by one test apparatus.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram showing an embodiment of a PDS optical line monitoring system of the present invention.

FIG. 2 is a diagram illustrating a configuration example of a fiber grating forming method using a phase mask (phase grating).

FIG. 3 is a diagram showing a transmission characteristic example 1 of a wavelength versus a transmittance of an optical fiber grating.

FIG. 4 is a diagram showing a transmission characteristic example 2 of a wavelength versus a transmittance of an optical fiber grating.

FIG. 5 is a diagram illustrating a transmission characteristic example n of wavelength versus transmittance of an optical fiber grating.

FIG. 6 is an observation characteristic diagram showing a relationship between a light intensity of a wavelength λ1 and a distance.

FIG. 7 is an observation characteristic diagram showing a relationship between a light intensity of a wavelength λ2 and a distance.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Optical transmitting / receiving apparatus 2 OTDR 3 WDM 4, 7 Optical transmission line 5 1: n optical multiplexing / branching apparatus 6 Optical fiber grating 8 Optical transmitting / receiving apparatus 9 Local station apparatus 10 Subscriber's premises apparatus 21 Phase mask 22 Fiber 23 Laser light

Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat II (reference) H04B 17/00 H04L 11/00 340 5K042 H04L 12/44 11/12 12/26 F term (reference) 2H038 AA22 AA34 BA25 2H050 AC84 AD06 AD16 5K002 AA05 BA02 BA04 BA21 DA02 DA12 EA06 FA01 5K030 GA14 HA10 HC06 JA02 JA04 JA10 JL03 JL08 LA17 MA04 MB01 MB20 MC01 5K033 AA06 CA17 DA15 DB02 DB05 DB16 DB20 DB22 EA02 EA05 5K042 BA02 CA10 CA13 FA01 LA08

Claims (6)

[Claims] 1. An indoor apparatus for transmitting a predetermined main signal and a test pulse light having a wavelength different from that of the main signal, and for analyzing the reflected / scattered and combined test light which has returned, and an input light. And a 1: n optical multiplexing / branching device that outputs the light in a band other than the test pulse light, and at least two lights having a transmission characteristic of a grating for blocking the band of the test pulse light in the fiber. And a fiber grating.
Optical line monitoring system. 2. A transmission characteristic of the optical fiber grating, wherein only a different wavelength λ1, λ2,..., Λn for each subscriber is transmitted in a stop band. PDS optical line monitoring system. 3. The indoor device transmits an optical transmitting / receiving device that transmits and receives the predetermined main signal, and transmits the test pulse light.
3. The PDS optical line monitoring system according to claim 1, further comprising: an OTDR that analyzes the test light, and a WDM that combines two types of light having different wavelengths. . 4. The PDS optical line monitoring system is connected to the optical fiber grating in a pair with an optical transmission line,
4. The PDS light beam according to claim 1, further comprising an optical transmitting / receiving device that converts an intra-office signal into an optical signal and sends out the same, and converts an optical signal from a subscriber side into an intra-office signal. Road monitoring system. 5. The test pulse light having a wavelength different from that of the main signal light and having a certain wavelength band is transmitted from the OTDR, and the test pulse light is multiplexed with the main signal by the WDM, and Sent to the optical transmission line, and said 1: n
5. The PD according to claim 4, wherein the light is branched into n by an optical coupling / branching device and sent to the optical fiber grating.
S optical line monitoring system. 6. The test light is reflected and scattered while propagating through the optical transmission line, and by analyzing light returning to the OTDR, an abnormality occurs at any point on any path of the optical transmission line. 6. The PDS optical line monitoring system according to claim 4, wherein it is possible to specify whether or not the PDS optical line is present.