JP3255214B2 - Optical subscriber line test method and apparatus - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention is used for optical subscriber communication. In particular, the present invention relates to a test of an optical subscriber transmission line that connects one center device and a plurality of optical subscriber devices in a one-to-many manner.

[0002]

2. Description of the Related Art In recent years, toward the realization of FTTH (Fiber To The Home), which can send a large amount of information to each home,
Research and development of optical subscriber systems are being actively pursued. Among them, TCM (Time Division Up / Down Multiplexing) and TDMA
PDS (Passive Double) by (time division user multiplexing)
The Star) system has attracted attention because the cost can be reduced by sharing the center device among a plurality of optical subscribers. In a transmission system in which user multiplexing is performed by a star coupler or the like, such as a PDS system, a monitoring system that can economically inspect a break in an optical fiber transmission line and other trouble locations without affecting communication is required.

FIG. 12 is a diagram for explaining a conventional optical subscriber line test method. The optical subscriber transmission line to be tested is a single center device (SLT: Subscriber Line Te
rminal) and a plurality of optical subscriber units (ONU: Optical Neural Network)
trwork Unit) 4 is a transmission line that connects one-to-many with
It is composed of a star coupler 2 and an optical fiber connected to the star coupler 2. However, in the figure, only the k-th (k = 1 to N) optical subscriber unit 4 is shown. In order to detect a failure point in the optical subscriber transmission line, a wavelength multiplexer / demultiplexer (WDM) 6 is arranged on the transmission line near the center device 1,
Optical reflection measurement device (OTDR: Optical Time Domain Refl)
ectmeter) 5 to input a light pulse as test light. Then, the light is reflected in the optical subscriber transmission line and is reflected by the light reflection measuring device 5.
The location of the failure in the optical subscriber transmission line is detected by the reflected light returning to step (1). At this time, the distance to the fault location can be determined from the time when the reflected light returns after the test light enters, and the optical subscriber unit 4
It is possible to determine which of the branch transmission lines has a fault by the presence or absence of the reflected light from the input / output end or the change in intensity.

Here, the input / output terminal (termination cable) of the optical subscriber unit 4 is connected to the center unit 1 so that the test light does not affect the communication between the center unit 1 and the optical subscriber unit 4. A wavelength selection filter 3 is inserted that transmits a wavelength used for communication with the device and reflects the wavelength of the test light. For example, when communication is performed in the 1.3 μm wavelength band, 1.65 μm is selected as the wavelength band of the test light, and the wavelength selection filter 3 transmits the 1.3 μm wavelength band and transmits 1.65 μm. A short-wavelength pass filter that reflects the above wavelength band is used. A wavelength of 1.3 μm for communication is transmitted, but a wavelength of 1.65 μm can be reflected, so that an optical subscriber transmission path can be tested without affecting communication.

[0005]

In the conventional optical subscriber line test method, when the distances from the branch point of the optical subscriber line to each optical subscriber unit are all different, each optical subscriber unit has a different optical path. By measuring the reflected light from the input / output end, it is possible to detect which of the branch transmission lines has a failure. However, this method can only detect a single point of failure, and when there are multiple points of failure, it is not possible to identify which reflected light is reflected from which branch transmission line, and the optical subscriber It is not possible to detect a fault in the transmission path.

This will be described with reference to FIG. In the following, a case of a break as an obstacle will be described as an example. When test light is input from the optical reflection measurement device, the test light is reflected by the star coupler, connector, etc. on the optical subscriber transmission line, and is further transmitted by the wavelength selection filter inserted at the input / output end of the optical subscriber device. reflect. The light reflection measuring device observes these reflected lights with the passage of time. When there is only one break point, reflected light from the break point is observed by a light reflection measuring device. Since the test light does not reach beyond the break point, no reflected light from the optical subscriber unit (the N-th optical subscriber unit in the figure) connected beyond the break point is observed. On the other hand, when there are two break points, two reflected lights from the break point are observed, and reflected lights from two optical subscriber units (first and N-th in the figure) are not observed. Therefore, there is a break in the two branch transmission lines, and the distance to the break point is known, but it is not possible to specify which branch transmission line has a break in which position.

Further, even when the same distance exists from the branch point of the optical subscriber transmission line to each optical subscriber unit, they cannot be distinguished.

This will be described with reference to FIG. Here, a case where the distances to the first and k-th optical subscriber units are the same will be described. In this case, the light reflected from the two optical subscriber units is observed by the light reflection measuring device so as to overlap each other. If there is a break in the branch transmission line connected to either of the two optical subscriber units, the reflected light from the break point is observed by a light reflection measuring device, and the light from the two optical subscriber units is The intensity of the reflected light decreases. For this reason, it is clear that a break has occurred in the branch transmission line connected to one of the two optical subscriber units, but they cannot be distinguished.

An object of the present invention is to provide an optical subscriber line test method and apparatus capable of solving the above problems and individually measuring the optical reflection of each branch transmission line of a point-to-multipoint optical subscriber line. The purpose is to provide.

[0010]

According to a first aspect of the present invention, an optical subscriber unit is connected to one center device and a plurality of optical subscriber units via optical coupling / branching means for connecting optical signals one-to-many. Optical fiber transmission line test method in which test light is incident on the optical transmission line from the center device side, and a defect location of the optical subscriber transmission line is detected by reflected light reflected in the optical subscriber transmission line and returned to the center device side. , The wavelengths used for communication between the center device and the optical subscriber unit are respectively transmitted to the input / output terminals of the optical coupling / branching unit on the side of the plurality of optical subscriber units, and the wavelengths of the test light and its reflected light are A filter means capable of switching between passing and blocking is provided, and by individually setting the filter means, each defect location between the optical coupling / branching means and the plurality of optical subscriber units is individually detected. Hikari subscriber biography Road test method is provided.

According to a second aspect of the present invention, the optical signal is
Test light is incident from the center device side to an optical subscriber transmission line connected to one center device and a plurality of optical subscriber devices via an optical coupling / branching means connected in many-to-many connection, and is reflected in the optical subscriber transmission line. In the optical subscriber line test method for detecting the defect location of the optical subscriber transmission line by the reflected light returning to the center device side, the optical coupling / branching means is connected to the input / output terminal of each of the plurality of optical subscriber devices. The first test light reflecting means that transmits the wavelength used for communication with the device and partially reflects the wavelength of the test light, and transmits the wavelength used for communication with the center test and substantially absorbs the wavelength of the test light The second test light reflecting means, which totally reflects the light, is arranged at a different distance for each of the plurality of optical subscriber units, and the multiple reflection between the first test light reflecting means and the second test light reflecting means. Due to the reflected light pulse train , Optical subscriber transmission line testing method characterized by identifying each transmission path between the wavelength division means and a plurality of optical subscriber units is provided.

According to a third aspect of the invention, the optical signal is
Test light is incident from the center device side to an optical subscriber transmission line connected to one center device and a plurality of optical subscriber devices via an optical coupling / branching means connected in many-to-many connection, and is reflected in the optical subscriber transmission line. An optical subscriber transmission line test device equipped with an optical reflection measuring device for detecting a defect location of an optical subscriber transmission line by reflected light returning to the center device side, Each end is provided with a filter means capable of transmitting a wavelength used for communication between the center device and the optical subscriber unit, and switching between pass and cutoff with respect to the wavelength of the test light and the reflected light. An optical subscriber line test apparatus is provided.

In this device, the filter means preferably includes means for changing a passing wavelength by changing a radius of curvature of an optical fiber constituting an optical subscriber transmission line.

According to a fourth aspect of the invention, the optical signal is
Test light is incident from the center device side to an optical subscriber transmission line connected to one center device and a plurality of optical subscriber devices via an optical coupling / branching means connected in many-to-many connection, and is reflected in the optical subscriber transmission line. A light reflection measuring device for detecting a defect location of an optical subscriber transmission line by reflected light returning to the center device side, and provided at each input / output end of a plurality of optical subscriber devices and used for communication with the center device. In an optical subscriber line test apparatus having a test light reflecting means for transmitting a wavelength and reflecting the wavelength of the test light, the test light reflecting means is disposed on the optical coupling / branching means side and used for communication with the center device. The first test light reflecting means which transmits the wavelength and partially reflects the wavelength of the test light, and the wavelength used for communication with the center test which is disposed on the optical subscriber unit side and transmits the wavelength of the test light. Virtually everything A second test light reflecting means for emitting light, wherein the first test light reflecting means and the second test light reflecting means are arranged at different distances for each of the plurality of optical subscriber units. A subscriber line test apparatus is provided.

[0015]

By inserting filter means having a variable passing wavelength on the optical subscriber unit side of the optical branching means, it is possible to separately test each branch transmission line. In addition, by providing two test light reflecting means at the input / output end of the optical subscriber unit and providing regularity to the reflected light when there is no obstacle, it is possible to identify individual branch transmission lines with the light reflection measuring device. it can.

[0016]

FIG. 1 is a block diagram showing an optical subscriber line test method and apparatus according to a first embodiment of the present invention. This embodiment is for testing an optical subscriber transmission line connecting one center device 1 and a plurality of optical subscriber devices 4 via a star coupler 2 which connects optical signals one-to-many.
Test light is incident on the optical subscriber transmission line from the center device 1 side, and the reflected light reflected in the optical subscriber transmission line and returned to the center device 1 side to detect a defect location in the optical subscriber transmission line. , A light reflection measuring device 5 and a wavelength multiplexer / demultiplexer 6. A wavelength selection filter 3 that transmits the wavelength λ ₀ used for communication and reflects the wavelength λ _{1 of the} test light is inserted at the input / output end of each optical subscriber unit 4. The input / output terminals of the star coupler 2 on the side of the optical subscriber unit 4 are variable so that the wavelength λ ₀ used for communication is transmitted and the test light and its reflected light wavelength λ ₁ can be passed or cut off. A wavelength filter 7 is provided.

FIG. 2 is a diagram for explaining the measuring operation. In the following, a case of a break as an obstacle will be described as an example. When test light is incident from the light reflection measuring device 5, the test light is reflected by the star coupler 2, the connector, and the like on the optical subscriber transmission line,
Further, the test light is reflected by the wavelength selection filter 3 inserted at the input / output end of the optical subscriber unit 4. Light reflection measuring device 5
Observes these reflected light over time. When all the variable wavelength filters 7 are turned on, the light reflected from each transmission path can be observed by the light reflection measuring device 5.

Here, the first and k-th optical subscriber units 4
Are arranged at an equal distance from the star coupler 2. At this time, the reflected light from the wavelength selection filter 3 inserted into each of the input / output terminals of the plurality of optical subscriber units 4 is observed in the light reflection measuring device 5 in an overlapping manner.
If there is a break in the branch transmission line to these optical subscriber units 4, the light reflection measuring device 5 observes reflected light from the break point. However, this alone cannot identify which branch transmission path has a break. Therefore,
Only the variable wavelength filter 7 of the branch transmission line connected to one optical subscriber unit 4 is turned on, and the others are turned off.
At this time, if there is reflected light from the break point, it is possible to identify that there is a break in the branch transmission path and its position. If there is no reflected light from the break point, it is found that there is no break in the branch transmission line.

Similarly, even when two or more branch transmission lines are broken or when a plurality of optical subscriber units 4 are arranged at the same distance from the star coupler, each branch transmission line is measured separately. And the location of the point of failure can be identified.

FIG. 3 is a flowchart showing the flow of this measurement. In this measurement, first, all the variable wavelength filters 7 are turned on, and the light reflection measurement is performed. The measured data obtained as a result is compared with the data at the time of no failure stored in the database in advance to determine the presence or absence of a transmission line failure location. If there is no data inconsistency, the measurement is terminated assuming that there is no failure in the transmission path. If there is a mismatch, the distances from the star coupler 2 to each optical subscriber unit 4 are all different, and if there is only one mismatch, the transmission path defect point is specified and the measurement ends. If there are two or more mismatches under the same conditions, all of the variable wavelength filters 7 are turned off, and a loss is applied to the test light and the wavelength λ _{1 of the} reflected light. Thereafter, the tunable wavelength filters 7 are sequentially turned on individually for the branch transmission paths which are regarded as having a problem, and the light reflection measuring device 5 is turned on.
To measure the reflected light and specify the location of the transmission path failure. If the distance from the star coupler 2 to each optical subscriber unit 4 is the same, the variable wavelength filters 7 are all turned off, and then the variable wavelength filters 7 are sequentially turned on one by one to perform light reflection measurement. The device 5 measures and detects the location of the fault.

FIG. 4 shows another measurement flow. In the measurement flow shown in FIG.
Is turned on, the measurement is performed, and when the location of the failure cannot be identified by the measurement, the measurement of each branch transmission line is performed. On the other hand, in the measurement flow shown in FIG. 4, individual branch transmission lines are measured from the beginning. That is, as in the case where the same distance exists from the star coupler 2 to each optical subscriber unit 4, first, all the variable wavelength filters 7 are turned off. Thereafter, the variable wavelength filter 7 is sequentially turned on, and the measurement and the detection of the fault location are performed by the light reflection measuring device 5.

FIG. 5 shows an example of the structure of the variable wavelength filter 7. In this structure, a movable lower block 71 and an upper block 72 formed on a substrate block are provided, and these are configured to mesh with each other in a saw-tooth shape. Then, the optical fiber 70, which has been loosely stretched in advance, is sandwiched between the lower block 71 and the partial block 72, so that the optical fiber 70 is curved to have a radius of curvature R, thereby emitting light in a long wavelength band. Accordingly, the wavelength lambda ₀ to be used in communication with the wavelength lambda ₁ of the test light and the reflected light lambda _1> lambda
When there is a relationship of ₀ , the wavelength λ ₀ is always passed, and the wavelength λ
₁ can be switched by passing or blocking.

FIG. 6 shows another example of the structure of the variable wavelength filter 8. In this structure, the optical fiber 70 previously wound in a circular shape is sandwiched between the left block 73 and the right block 74,
By pressing these with a spring 75, the radius of curvature of the optical fiber 70 can be changed and the wavelength of the test light can be emitted. To obtain the desired characteristics, the optical fiber 7
0 may be wound n times in advance.

FIG. 7 shows another example of the structure of the variable wavelength filter 7. In this structure, a circular block 77 having a radius R provided on the lower substrate block 76 such that the radius of curvature becomes R when the optical fiber is drawn is provided. By applying a pulling force to one side of an optical fiber that has been loosely stretched in advance, the radius of curvature can be changed and the wavelength of the test light can be emitted. This structure can be connected in multiple stages to obtain desired characteristics.

FIG. 8 is a diagram for explaining the operation principle of the variable wavelength filters shown in FIGS. 5 to 7, and shows the relationship between wavelength and loss using the radius of curvature R as a parameter. FIG. 9 is a block diagram showing the optical subscriber line test method and apparatus according to the second embodiment of the present invention, in which it is understood that the loss of the long wavelength is increased by reducing the radius of curvature. This embodiment has a configuration of a wavelength selection filter provided at each input / output end of each optical subscriber unit 4 for transmitting a wavelength λ ₀ used for communication with the center device 1 and reflecting for a wavelength λ ₁ of test light. Is different from the first embodiment, a first wavelength selection filter 31 which is disposed on the star coupler 2 side and transmits the wavelength λ _{0 and} partially reflects the wavelength λ ₁ , and the optical subscriber unit 4.
A second wavelength selection filter 32 disposed on the side and transmitting wavelength λ ₀ and reflecting substantially all of wavelength λ ₁ . These wavelength selection filters 31 and 32 are arranged at different distances for each optical subscriber unit 4.

FIG. 10 is a diagram for explaining the operation of the second embodiment, and FIG. 11 shows a measurement flow thereof. By using the two wavelength selection filters 31 and 32, multiple reflection occurs,
In the light reflection measuring device 5, the pulse interval is 2 L / ν, and the amplitude ratio is (1-x): x ² : (1-x) x ² : (1-x)
² × ² :...: (1-x) ^k−2 × ² :. Here, L is the distance between the wavelength selection filters 31 and 32, ν is the light transmission speed in the optical fiber, and x is the transmittance of the wavelength selection filter 31. Therefore, when the pulse train is observed, there is no failure in the branch transmission line, and when the pulse train is not observed, it is understood that the branch transmission line has a failure. The failure location can be specified by the reflected light from the failure point, as in the first embodiment.

[0027]

As described above, according to the present invention, the optical subscriber transmission path is economically tested regardless of the transmission distance between the star coupler and each optical subscriber unit and the number of break locations. be able to.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of the present invention.

FIG. 2 illustrates a measurement operation.

FIG. 3 is a diagram showing a measurement flow.

FIG. 4 is a diagram showing another measurement flow.

FIG. 5 is a diagram showing a structural example of a tunable filter.

FIG. 6 is a diagram showing another example of the structure of the variable wavelength filter.

FIG. 7 is a diagram showing another example of the structure of the variable wavelength filter.

FIG. 8 is a view for explaining the operation principle of the variable wavelength filter shown in FIGS. 5 to 7;

FIG. 9 is a block diagram showing a second embodiment of the present invention.

FIG. 10 is a diagram for explaining the operation of the second embodiment.

FIG. 11 is a diagram showing a measurement flow.

FIG. 12 is a diagram illustrating a conventional optical subscriber line test method.

FIG. 13 is a diagram illustrating a problem of the conventional example.

FIG. 14 is a diagram illustrating a problem of a conventional example.

[Explanation of symbols]

 Reference Signs List 1 center device 2 star coupler 3, 31, 32 wavelength selection filter 4 optical subscriber device 5 optical reflection measuring device 6 wavelength multiplexer / demultiplexer 7 variable wavelength filter

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04B 3/46 H04B 17/00 H04B 10/08

Claims (5)

(57) [Claims] 1. Optical combining / branching means for connecting optical signals in a one-to-many manner.
To one optical network unit and one optical network unit
Test light is transmitted from the center device to the optical transmission line
And is reflected in the optical subscriber transmission line to the center device side.
Detects the location of a defect in the optical subscriber transmission line by returning reflected light
Optical subscriber line test methodAt each input / output end of the plurality of optical subscriber units,
Between one center device and the plurality of optical subscriber units.
The wavelength used for communication is transmitted and the test light is reflected
Insert selective reflection means,  Input / output of the optical coupling / branching means on the side of the plurality of optical subscriber units
On the edgeIsBefore eachNoteThe wavelength used for transmission is transmitted,
Pass or block the wavelength of the test light and its reflected light.
By providing filter means capable of switching the cutoff, by individually setting the filter means,
Between the branching means and the plurality of optical subscriber units;
Optical subscriber characterized by individually detecting defect locations
Transmission path test method. 2. A test light is incident from the center device side to an optical subscriber transmission line connecting one center device and a plurality of optical subscriber devices via optical coupling / branching means for connecting one-to-many optical signals. An optical subscriber line test method for detecting a defect location of the optical subscriber line by reflected light reflected in the optical subscriber line and returning to the center device side, wherein the plurality of optical subscriber units A first test light reflecting unit that transmits a wavelength used for communication with the center device and partially reflects a wavelength of the test light from the optical coupling / branching unit side to each input / output end; And a second test light reflecting means that transmits a wavelength used for communication with the test light and reflects substantially all of the wavelength of the test light at a different distance for each of the plurality of optical subscriber units. Test light reflecting means and second By the interval of the pulse train of the reflected light caused by multiple reflection between the test light reflecting means <br/> is, to identify each transmission path between the optical multiplexer branching unit and the plurality of optical subscriber units An optical subscriber line test method. 3. An optical multiplexing / branching means for connecting optical signals in a one-to-many manner.
To one optical network unit and one optical network unit
Test light is transmitted from the center device to the optical transmission line
Incident on the optical subscriber line and reflected at the optical subscriber line.
Defective field of the optical subscriber transmission line due to reflected light returning to the device side
Optical transmission line test equipped with optical reflection measuring device for detecting locations
Test equipment,At each input / output end of the plurality of optical subscriber units,
Between one center device and the plurality of optical subscriber units.
The wavelength used for communication is transmitted and the test light is reflected
Equipped with selective reflection means,  Input / output of the optical coupling / branching means on the side of the plurality of optical subscriber units
Front to each endNoteThe wavelength used for transmission is transmitted and
Pass or block the wavelength of the test light and its reflected light
Light characterized by comprising filter means capable of switching between
Subscriber transmission line test equipment. 4. An optical subscriber line test apparatus according to claim 3, wherein said filter means includes means for changing a passing wavelength by changing a radius of curvature of an optical fiber constituting said optical subscriber line. 5. A test light is incident from the center device side to an optical subscriber transmission line connecting one center device and a plurality of optical subscriber devices via an optical multiplexing / branching means for connecting one-to-many optical signals. A light reflection measuring device for detecting a defect location of the optical subscriber transmission line by reflected light reflected in the optical subscriber transmission line and returning to the center device side; An optical subscriber line test apparatus provided at an output end and having a test light reflecting means for transmitting a wavelength used for communication with the one center device and reflecting a wavelength of the test light; A first test light reflecting unit disposed on the side of the optical coupling / branching unit and transmitting a wavelength used for communication with the center device and partially reflecting a wavelength of the test light; Placed on the device side A second test light reflecting means for transmitting a wavelength used for communication with the center test and reflecting substantially all of the wavelength of the test light, and wherein the first test light reflecting means and the second The test light reflecting means is disposed at a different distance for each of the plurality of optical subscriber units , and the light reflection measuring device is disposed in front of the first test light reflecting means.
Caused by multiple reflections with the second test light reflecting means.
The light combining / branching means and the plurality
An optical subscriber line test apparatus for identifying each transmission path between the optical subscriber unit and the optical subscriber unit.