JP2004317402A - Measuring method for optical line loss and measuring device therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measuring method for an optical line loss that precisely determines the loss of an optical line between transmission devices by one time of measurement, and a measuring device therefor. <P>SOLUTION: The measuring device for the optical line loss is constituted of two optical reflectors 2, 3 connected to the both ends of the optical line (optical fibers 4, 5), an optical multiplexer/demultiplexer 6 inserted into the way of the optical line, and the optical pulse testing machine 1 connected to the c-port of the optical multiplexer/demultiplexer unit 6. By using the measuring device, the loss of the optical line of an object to be measured is accurately calculated at one time of measurement, by measuring the primary reflectivity that testing light entered into from the optical pulse testing machine 1 is reflected from the optical reflector 2 at the far end of the optical line of the object; and the second reflectivity that this primary reflected light is reflected by the optical reflector 3 at the near end thereof and thereafter, is again reflected by the optical reflector 2 at the far end, when the reflection decreasing quantities of the two optical reflectors 2, 3 are known. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical line loss measuring method and an optical line loss measuring method for measuring the optical loss of an optical line composed of an optical fiber.
[0002]
[Prior art]
A device has been developed to measure optical loss during the installation and maintenance of optical lines where multiple optical fiber cables are connected by fusion or connectors, etc. It is designed so that it can be tested and monitored without giving it.
[0003]
(Conventional example 1)
FIG. 13 is a configuration diagram showing an example of a conventional optical line loss measuring device, and is a configuration of a system that can perform a test without affecting communication even when the transmission device is in service.
[0004]
As shown in FIG. 13, the optical line loss measuring device of the conventional example is connected to an optical multiplexer / demultiplexer 6 to which an optical fiber 4 to be measured is connected, and to the branch side (port c) of the optical multiplexer / demultiplexer 6. The optical pulse tester 1, a communication light cutoff filter 18 connected between the optical coupler 6 and the optical pulse tester 1, and both ends of the optical fiber 4 and the optical fiber 5 constituting the optical line are connected. Test light blocking filters 41 and 40 are provided. The transmission devices 16 and 17 are connected to the test light blocking filters 41 and 40, and optical signals from the transmission devices 16 and 17 are transmitted and received between the optical fibers 4 and 5, and transmitted.
[0005]
The optical multiplexer / demultiplexer 6 includes three 1 × 2 optical input / output ports (a, b, and c ports), and the port a to the port b, the port c to the port b, the port b to the port a, and Light is emitted to any of the ports c. One end of the optical fiber 5 is connected to the port a of the optical coupler 6, and a test light cutoff filter 41 is connected to the other end of the optical fiber 5. One end of the optical fiber 4 is connected to the port b of the optical coupler 6, and a test light cutoff filter 40 is attached to the other end of the optical fiber 4. The optical pulse tester 1 is attached to a port c of the optical coupler 6 via a connector 9. The optical fiber 4 is actually provided with a test light blocking filter 40 via a fusion splicing point 10 and a connector connection point 11.
[0006]
In the conventional optical line loss measuring device, test light blocking filters 40 and 41 having characteristics of transmitting communication light and blocking test light are inserted in front of the transmission devices 16 and 17, respectively. Further, a communication light cutoff filter 18 having characteristics of blocking communication light and transmitting test light is inserted in front of the optical pulse tester 1. With such a configuration, the optical pulse tester 1 uses a test wavelength (λ2: 1650 nm, for example) different from the communication wavelength (λ1: 1310 nm, for example) used between the transmission devices 16 and 17 as test light. Thus, the test can be performed without affecting the communication light.
[0007]
FIG. 14 is a graph of an OTDR waveform measured by the optical pulse tester 1 of the conventional optical line loss measuring device.
When the vertical axis is the backscattered light level and the horizontal axis is the distance, the backscattering level at the near end of the optical fiber 4 is X0 (dB) and the backscattering light level at the far end is X1 (dB). The optical loss FLoss (dB) of the fiber 4 is obtained by the following equation.
FLoss = X0-X1
In addition, the loss due to the fusion splice point 10 and the connector connection point 11 in the middle of the optical fiber 4 is included in the FLoss.
[0008]
(Conventional example 2)
FIG. 15 is a configuration diagram showing another example of the conventional optical line loss measuring device.
In this conventional example, the basic configuration except for the optical multiplexer / demultiplexer 27 is the same as that of the conventional example 1 shown in FIG.
[0009]
The optical line loss measuring device of this conventional example is different in that a 4-port optical multiplexer / demultiplexer 27 is used instead of the 3-port optical multiplexer / demultiplexer 6.
The optical multiplexer / demultiplexer 27 includes four 2 × 2 optical input / output ports (a, b, c, and d ports), and switches from a port to b port and d port, or c port to b port and d port. Alternatively, light is emitted from port b to port a and port c, or from port d to port a and port c. The optical pulse tester 1 is connected to the d port of the optical coupler 27 via the connector 28 when measuring the optical fiber 5.
[0010]
That is, when measuring the optical fiber 4, the optical pulse tester 1 is connected to the port c of the optical multiplexer / demultiplexer 27 via the connector 9, and when measuring the optical fiber 5, the connector 28 is used. Thus, the optical pulse tester 1 is connected to the d port of the optical multiplexer / demultiplexer 27. As described above, by using the four-port optical coupler / splitter 27 and changing the connection port of the optical pulse tester 1, it is possible to measure the optical fibers 4 and 5, respectively.
[0011]
(Conventional example 3)
FIG. 16 is a configuration diagram showing another example of the conventional optical line loss measuring device, which is a system in which an optical switch is combined with the optical line loss measuring device of Conventional Example 1 shown in FIG.
The basic configuration of this conventional example other than the optical switch is the same as that of the first conventional example shown in FIG.
[0012]
In this conventional example, a 1 × N optical switch 25 is used, the optical pulse tester 1 is connected to the head 26 on one core side, and the c port of the optical coupler 6 is connected to the N core side via the connector 9. It is a configuration to connect. In FIG. 16, only one optical line is shown for convenience. However, actually, a plurality of optical fibers 4 and 5 are connected to the 1 × N optical switch 25 via the c ports of the plurality of optical couplers 6 and the connector 9. Connected to N-core side. The head 26 is configured to be mechanically movable in the longitudinal direction of the 1 × N optical switch 25, and by moving, selects any one of the N-fiber side optical fibers.
[0013]
In other words, by switching the N-fiber side optical fiber to which the optical pulse tester 1 is connected by the 1 × N optical switch 25, it is possible to test a plurality of optical fibers 4 with one optical pulse tester 1. Thus, it is not necessary to manually attach the optical pulse tester 1 and the test light cutoff filter 18 to the optical coupler 6 every time measurement is performed.
[0014]
(Conventional example 4)
FIG. 17 is a configuration diagram showing another example of the conventional optical line loss measuring device, which is a system in which an optical switch is combined with the optical line loss measuring device of Conventional Example 2 shown in FIG.
The basic configuration of this conventional example except for the optical switch is the same as that of the conventional example 2 shown in FIG.
[0015]
In this conventional example, a 1 × N optical switch 25 is used, the optical pulse tester 1 is connected to the head 26 on the one core side, and the c port of the optical coupler 27 is connected to the connector 9 on one head on the N core side. And the d port of the optical multiplexer / demultiplexer 27 is connected to the other one of the N-core side via a connector 28. Although only one optical line is shown in FIG. 17 for convenience, a plurality of optical fibers 4 and 5 are actually connected to the c port, the connector 9 and the d port of the optical multiplexer / demultiplexer 27 and to the connector 28. Is connected to the N-core side of the 1 × N optical switch 25.
[0016]
Also in this conventional example, the 1 × N optical switch 25 switches the N-fiber side optical fiber to which the optical pulse tester 1 is connected, so that one optical pulse tester 1 can use a plurality of optical fibers 4 and optical fibers. 5 can be tested, and the optical pulse tester 1 and the test light cutoff filter 18 do not need to be manually attached to the optical splitter 27 for each measurement.
[0017]
The systems shown in FIGS. 16 and 17 are introduced in Non-Patent Document 1 and the like under the name of an optical line test system.
[0018]
[Non-patent document 1]
"Let's talk about optical access networks and π systems", Telecommunications Association, 1999, P111-P114
[0019]
[Problems to be solved by the invention]
FIG. 18 shows a realistic connection configuration of optical lines in a conventional optical line loss measuring device.
This shows the optical line and the optical line loss measuring device of the first embodiment shown in FIG.
[0020]
As shown in FIG. 18, the optical coupler 6 and the optical fiber 4 are actually connected via a connector 7. Further, the connection point of the connector 8 and the test light cutoff filter 40 may be close to each other on the far end side of the optical fiber 4. That is, when there is a connection point by fusion or a connector near the far end, accurate measurement may not be possible due to the influence of backscattered light due to the connection point.
[0021]
FIG. 19 is a graph of the OTDR waveform measured by the optical line loss measuring device in the realistic optical line shown in FIG.
As shown in FIG. 19, at the near end of the measured waveform, the backscattered light level at the near end cannot be accurately obtained due to the Fresnel reflection 42 by the connector 7. Further, due to the Fresnel reflection 43 generated at the connector 8, the backscattered light level at the far end cannot be accurately obtained. In other words, since there are connector connection points and fusion connection points that affect the backscattered light level near the near end and far end of the optical line to be measured, the characteristics of the optical line are measured. Is making it difficult. This is a problem that also occurs when the 1 × N optical switch 25 shown in FIG. 16 is used.
[0022]
Further, in the conventional examples 1 and 3 shown in FIGS. 13 and 16, only the loss of the optical fiber 4 can be measured. In the conventional examples 2 and 4 shown in FIGS. 15 and 17, the loss of the optical fibers 4 and 5 can be measured. However, at the time of the measurement, it is necessary to perform the measurement at least twice as described above. .
[0023]
Further, since only the loss of the optical fiber 4 or the optical fiber 5 can be measured, the optical line between the transmission device 16 and the transmission device 17, that is, the entire optical line including the optical fiber 5, the optical coupler 6, and the optical fiber 4 can be measured. The loss could not be determined by the light pulse tester 1.
[0024]
That is, in the conventional optical line loss measuring method and apparatus, even for one optical line, reconnection of the optical pulse tester 1 and at least two or more measurements are necessary for measuring the entire optical line. In addition, when there is a connection point such as a connector near the end of the optical line, the measurement is inaccurate.
[0025]
SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to provide an optical line loss measuring method and an optical line loss measuring device for accurately determining an optical line loss between transmission devices in one measurement.
[0026]
[Means for Solving the Problems]
An optical line loss measuring method according to the present invention that solves the above problems,
Inserting and connecting an optical multiplexing / branching unit for multiplexing / branching light into an optical line made of an optical fiber,
Optical testing means for measuring the characteristics of the optical line is connected to one of the branching sides of the optical coupling / branching means,
Light reflecting means for reflecting the test light is connected to both ends of the optical line,
The known return loss of one of the light reflection means is set to RLossB (dB),
When the known return loss of the other light reflection means is RLossA (dB),
While the test light is incident on the optical path from the optical test means, the response light generated on the optical path by the test light is received by the optical test means,
From the response light waveform
At the position of the end of the optical line, the primary reflection level RB (dB) of one of the light reflecting means observed by the light testing means,
The level RA (dB) of the secondary reflection of one of the light reflecting means observed by the optical testing means is measured at a time at a position separated from the position where the primary reflection is measured by the length of the optical path. do it,
The optical loss FLoss (dB) of the optical line is
FLoss = RB + (RLossB / 2) -RA + (RLossA / 2)
It is characterized by being obtained from the following equation.
Note that an optical pulse is used as the test light, and the response light is composed of backscattered light and Fresnel reflected light generated in the optical path by the optical pulse.
[0027]
An optical line loss measuring method according to the present invention that solves the above problems,
In the above optical line loss measuring method,
Transmission means for transmitting and receiving communication light having a wavelength different from the test light is connected to each of the light reflecting means at both ends,
A light blocking means for transmitting the test light and blocking the communication light is connected between the light testing means and the light branching means,
The light reflecting means transmits the communication light and reflects and blocks the test light.
[0028]
An optical line loss measuring method according to the present invention that solves the above problems,
In the above optical line loss measuring method,
The optical coupling / branching means has three 1 × 2 optical input / output ports,
An optical line is connected to one of the two ports and one port of the optical coupling / branching means,
An optical test unit is connected to the other of the two ports of the optical coupling / branching unit.
[0029]
An optical line loss measuring method according to the present invention that solves the above problems,
In the above optical line loss measuring method,
The optical coupling / branching means has four 2 × 2 optical input / output ports,
An optical line is connected to one of the two ports of the optical coupling / branching means and one of the other two ports,
Optical testing means is connected to the other of the two ports of the optical coupling / branching means,
A non-reflection terminal that does not reflect the test light or a refractive index matching material is connected to the other of the two ports of the optical coupling / branching means.
[0030]
An optical line loss measuring device according to the present invention that solves the above problems,
An optical multiplexing / branching unit that is inserted into and connected to an optical line made of an optical fiber, and multiplexes and branches light;
It is connected to one of the branching sides of the optical multiplexing / branching means. The test light is incident on the optical line, the response light generated on the optical line by the test light is received, and the characteristic of the optical line is measured from the waveform of the response light. Light testing means
Light-reflecting means connected to both ends of the optical line and reflecting test light,
The known return loss of one of the light reflection means is set to RLossB (dB),
The known return loss of the other light reflection means is defined as RLossA (dB),
At the position of the end of the optical line, the primary reflection level of one of the light reflecting means observed and measured by the light testing means is RB (dB),
The level of the secondary reflection of one of the light reflecting means observed and measured by the optical testing means at a position separated by the length of the optical path from the position at which the primary reflection was measured is RA (dB). If you do
The optical loss FLoss (dB) of the optical line is
FLoss = RB + (RLossB / 2) -RA + (RLossA / 2)
Is obtained from the following equation.
[0031]
An optical line loss measuring device according to the present invention that solves the above problems,
In the optical line loss measuring device,
Transmission means connected to each of the light reflection means at both ends and transmitting and receiving communication light having a wavelength different from the test light,
A light blocking unit connected between the optical testing unit and the optical branching unit, transmitting the test light, and blocking the communication light,
The light reflecting means transmits the communication light and reflects and blocks the test light.
[0032]
An optical line loss measuring device according to the present invention that solves the above problems,
In the optical line loss measuring device,
The optical coupling / branching unit has three 1 × 2 optical input / output ports,
An optical line is connected to one of the two-port side and the one-port side of the optical coupling / branching means;
The optical testing means is connected to the other of the two ports of the optical coupling / branching means.
[0033]
An optical line loss measuring device according to the present invention that solves the above problems,
In the optical line loss measuring device,
The optical coupling / branching means has four 2 × 2 optical input / output ports,
An optical line is connected to one of the two port sides of the optical coupling / branching means and one of the other two port sides;
An optical test means connected to the other of the two ports of the optical coupling / branching means;
A non-reflection terminal or a refractive index matching material that does not reflect the test light is connected to the other of the two ports on the other side of the optical coupling / branching means.
[0034]
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention provides two optical reflectors (light reflecting means) connected to both ends of an optical line when measuring optical loss of an optical line composed of an optical fiber, and an optical splitter inserted in the optical line. The return loss of the two optical reflectors is known using an optical line loss measuring device composed of (optical coupling / branching means) and an optical pulse tester (optical testing means) connected to the optical coupling / branching device. At this time, the test light incident from the optical pulse tester reflects the primary reflection level reflected from the light reflector at the far end of the optical path to be measured, and the primary reflection is reflected to the light reflector at the near end. By measuring the secondary reflection level that has been reflected and reflected again from the light reflector at the far end, it is possible to accurately calculate the loss of the optical line to be measured with only one measurement without changing the connection. It is.
[0035]
In the conventional optical line loss measuring device, only a test light cutoff filter is provided at both ends of the optical line so that the test light does not affect the communication light. No consideration was given to reflection. However, in the present invention, at least the light reflectors for reflecting the test light are provided at both ends of the optical line, and the above effects are realized by positively utilizing the reflection. Therefore, some embodiments of an optical line loss measuring method and an optical line loss measuring device according to the present invention will be described with reference to the drawings shown below.
[0036]
(Example 1)
FIG. 1 is a configuration diagram showing an example of an embodiment of an optical line loss measuring device according to the present invention.
[0037]
As shown in FIG. 1, the optical line loss measuring apparatus according to the present embodiment is inserted and connected in the middle of an optical line to be measured (comprising optical fibers 4, 5 and the like), and is connected to a 1.times. An optical pulse splitter 6 connected to a branch port of the optical splitter 6 for measuring characteristics of the optical line, and optical reflectors 2 and 3 connected to both ends of the optical line. Have. For convenience, in FIG. 1, the light reflector 2 is a light reflector at the far end, and the light reflector 3 is a light reflector at the near end.
[0038]
In the case of the present invention, the optical line to be measured is an optical line between the light reflector 2 and the light reflector 3, that is, a light path (to be described later) actually used by a transmission device (transmission means) of the optical communication. As shown specifically in FIG. 1, the optical fiber 5, the optical coupler / splitter 6, the connector 7, the optical fiber 4 (including the fusion splicing point 10 and the connector connection point 11), and This is the part of the connector 8.
[0039]
The optical multiplexer / demultiplexer 6 includes three 1 × 2 optical input / output ports (a, b, and c ports), and the port a to the port b, the port c to the port b, the port b to the port a, and Light is emitted to any of the ports c. One end of the optical fiber 5 is connected to the port a of the optical coupler 6, and the light reflector 3 is connected to the other end of the optical fiber 5. One end of the optical fiber 4 is connected to the port b of the optical coupler 6 via a connector 7, and the optical reflector 2 is connected to the other end of the optical fiber 4 via a connector 8. . The optical pulse tester 1 is attached to a port c of the optical coupler 6 via a connector 9. The optical fiber 4 may have a fusion splicing point 10 and a connector connection point 11 as shown in FIG. In addition, as the optical coupler 6, a wavelength-independent coupler is used.
[0040]
The optical pulse tester 1 has a light source that generates pulsed light having a predetermined wavelength and predetermined power, and has an optical sensor and the like that measures a reflected wave of the pulsed light. At the time of measurement, pulse light serving as test light enters the optical line from port c of the optical coupler / shunter 6, and response light composed of backscattered light and Fresnel reflected light generated on the optical line by the test light is received. The characteristics of the optical line are measured from the light waveform.
[0041]
The light reflectors 2 and 3 may be any as long as they reflect the test light incident from the light pulse tester 1. The known return loss of the light reflector 2 is RLossB (dB), and the known return loss of the light reflector 3 is RLosA (dB).
[0042]
Next, a measuring method using the optical line loss measuring device of the present embodiment will be described with reference to FIGS.
FIG. 2 is a diagram for explaining Fresnel reflection in the optical line loss measuring apparatus of the present embodiment shown in FIG. 1, and FIG. 3 is a diagram for explaining Fresnel secondary reflection.
[0043]
In the measurement method of the present embodiment, in order to obtain the loss FLoss of the optical line to be measured, the Fresnel reflection 12 and the Fresnel secondary reflection 13 from the light reflector 2 are measured using the light pulse tester 1. There is a need.
[0044]
Specifically, the optical pulse output from the optical pulse tester 1 is incident on the optical fiber 4 via the optical coupler / splitter 6. Thereafter, the light pulse propagates through the optical fiber 4 and is reflected by the light reflector 2.
[0045]
The light pulse reflected by the light reflector 2 propagates through the optical fiber 4, enters the port b of the optical coupler / splitter 6, and is split into the port c and the port a.
[0046]
The light pulse output from the port c returns to the light pulse tester 1 and is observed as the Fresnel reflection 12 at the position of the light reflector 2. That is, assuming that the length of the optical fiber 4 is X (km), the Fresnel reflection 12 from the optical reflector 2 located at the far end of the optical line is generated by the optical pulse tester 1 at the far end of the optical line. At the position X (km), it is measured as the reflection level RB (dB). In FIG. 2, the path of the light pulse of the Fresnel reflection 12 is shown by a dotted line.
[0047]
On the other hand, the optical pulse output from the port a of the optical coupler 6 propagates through the optical fiber 5, is reflected by the optical reflector 3, propagates through the optical fiber 5 again, returns to the port a of the optical coupler 6 and b Emitted from the port.
[0048]
The optical pulse emitted from the port b of the optical coupler 6 is incident on the optical fiber 4. Thereafter, the optical pulse propagates through the optical fiber 4 again and is reflected by the optical reflector 2. The light pulse reflected by the light reflector 2 propagates through the optical fiber 4, enters the port b of the optical coupler / splitter 6, and is split into the port c and the port a.
[0049]
The light pulse output from the port c returns to the light pulse tester 1 and is reflected from the position X (km) of the light reflector 2 to a position farther from the light reflector 2 by the distance between the light reflector 2 and the light reflector 3. Is observed as Fresnel secondary reflection 13 from the vessel 2. That is, assuming that the length of the optical fiber 5 is Y (km), the Fresnel secondary reflection 13 from the optical reflector 2 located at the far end of the optical line is measured by the optical pulse tester 1 and the Fresnel reflection 12 is measured. Is measured as a reflection level RA (dB) at a position [X + X + Y (km)] separated by [X + Y (km)] the length of the optical line from the position X (km) at the far end of the optical line. . In FIG. 3, the path of the optical pulse of the Fresnel secondary reflection 13 is indicated by a dotted line.
[0050]
FIG. 4 is a graph of an OTDR (Optical Time Domain Reflectmeter) waveform measured by the optical line loss measuring device and the measuring method according to the present embodiment.
In this graph, the level of the backscattered light due to Rayleigh scattering is omitted for easy understanding.
[0051]
As shown in FIG. 4, in the optical line loss measuring device and the measuring method according to the present embodiment, the level of each of the Fresnel reflection 12 and the Fresnel secondary reflection 13 with respect to the light reflector 2 is measured by performing only one measurement. We can see that we can do it.
[0052]
Since the return loss RLossB (dB) of the light reflector 2 and the return loss RLosA (dB) of the light reflector 3 are known, the Fresnel reflection level of the light reflector 2 measured by the light pulse tester 1 is RB ( dB), when the Fresnel secondary reflection level of the optical reflector 2 is RA (dB), the entire optical loss of the optical fiber 5, the optical coupler 6 and the optical fiber line 4, that is, the light from the optical reflector 3 FLloss (dB), which is the loss of the optical line between the reflectors 2, can be obtained by the following equation.
FLoss = RB + (RLossB / 2) -RA + (RLossA / 2)
Here, the return loss of the light reflectors 2 and 3 is measured in advance when the light reflectors 2 and 3 are manufactured.
[0053]
The above equation represents the relationship between the reflection level RB (dB) of the Fresnel reflection 12 observed on the path shown in FIG. 2 and the reflection level RA (dB) of the Fresnel secondary reflection 13 observed on the path shown in FIG. The difference is equal to the loss FLoss (dB) of the optical line between the light reflector 2 and the light reflector 3, and furthermore, since the return loss of the light reflector 2 and the light reflector 3 is not 0 dB, they are not equal to each other. The return loss RLossB (dB) and RLossA (dB) are corrected.
[0054]
The reflection of the light reflector 2 and the light reflector 3 needs to be sufficiently larger than the Fresnel reflection amount generated in another connector, for example, the connector 7 at the near end of the optical fiber 4 or the connector 8 at the far end. For this reason, the return loss of the light reflector 2 and the light reflector 3 can be accurately measured when the reflection loss is 0 to 1 dB, which is closer to perfect reflection. Further, the light emitting cycle of the light pulse of the light pulse tester 1 needs to have a sufficient light emitting cycle interval so that the Fresnel reflection 12 and the Fresnel secondary reflection 13 are not mixed.
[0055]
(Example 2)
FIG. 5 is a configuration diagram showing another example of the embodiment of the optical line loss measuring device according to the present invention.
Note that, in the optical line loss measuring device of the present embodiment, the same parts as those of the optical line loss measuring device shown in Embodiment 1 are denoted by the same reference numerals, and redundant description will be omitted.
[0056]
As shown in FIG. 5, the optical line loss measuring device according to the present embodiment is inserted and connected in the middle of an optical line to be measured (consisting of optical fibers 4, 5 and the like), and is connected and splits light. An optical pulse tester 1 connected to a branch-side port of the optical multiplexer / demultiplexer 6 for measuring characteristics of an optical line; optical reflectors 14 and 15 connected to both ends of the optical line; 6 and a communication light cutoff filter 18 connected between the optical pulse tester 1.
[0057]
The light reflectors 14 and 15 have characteristics of transmitting communication light λ1 from the transmission devices 16 and 17 and reflecting test light λ2 from the optical pulse tester 1 (for details, see FIG. (See FIG. 7). Further, the communication light cutoff filter 18 provided in front of the optical pulse tester 1 has a characteristic of blocking the communication light λ1 and transmitting the test light λ2.
[0058]
Transmission devices 16 and 17 for transmitting and receiving optical signals by communication light are connected to the light reflectors 14 and 15. In the transmission devices 16 and 17, communication between the optical lines is performed using communication light having a wavelength λ1 different from the wavelength λ2 of the test light. With such a configuration, the communication light from the transmission devices 16 and 17 and the test light from the optical pulse tester 1 do not affect each other, and a loss test of the optical line can be performed. . That is, the optical line loss measuring device of the present embodiment is a system that can perform a test without affecting communication even when the transmission devices 16 and 17 are in service.
[0059]
Specifically, the optical pulse tester 1 uses a wavelength λ2 (eg, 1650 nm) of the test light different from the wavelength λ1 (eg, 1310 nm) of the communication light used between the transmission devices 16 and 17 as the test light. Since the optical reflectors 14 and 15 reflect and block the test light from the optical pulse tester 1, the loss of the optical line is measured in the same manner as in the measurement method of the first embodiment without affecting communication. can do.
[0060]
FIG. 6 is a schematic configuration diagram of the light reflectors 14 and 15 used in the present embodiment.
As shown in FIG. 6, the light reflecting elements 20 provided on the light reflectors 14 and 15 to which the optical fiber 19 is connected transmit the communication light wavelength λ1 so that the test light does not affect the communication light. The wavelength λ2 of the test light has characteristics of reflecting and blocking.
[0061]
FIGS. 7A and 7B are cross-sectional views of a more specific configuration example of the light reflector having the above characteristics.
The light reflectors 14 and 15 shown in FIG. 7A use a dielectric multilayer filter 23. The dielectric multilayer filter 23 transmits a specific wavelength of light and reflects other specific wavelengths of light with high efficiency by laminating a plurality of appropriate dielectric films. The specific configuration of the light reflectors 14 and 15 is a structure in which a dielectric multilayer film filter 23 is provided in a housing 21 holding an SC connector ferrule 22, and an optical fiber 19 is connected to the housing 21. And a light reflector having the above characteristics.
[0062]
The light reflectors 14 and 15 shown in FIG. 7B use a fiber grating filter 24. The fiber grating filter 24 is capable of transmitting light of a specific wavelength and reflecting light of another specific wavelength arbitrarily by periodically changing the refractive index of the core of the fiber. The specific configuration of the light reflectors 14 and 15 is a structure in which the core portion of the optical fiber in the SC connector ferrule 22 is a fiber grating filter 24. By connecting the optical fiber 19 to the housing 21, Is obtained.
[0063]
In this embodiment, an SC connector is used as the connector ferrule. However, a light reflector having the above-described characteristics can be realized with a similar structure using an MU connector or an LC connector.
[0064]
(Example 3)
FIG. 8 is a modification example of the optical line loss measuring device of the present embodiment shown in FIG. 5, and is a configuration diagram of a system in which 1 × N optical switches 25 are combined.
The optical line loss measuring device according to the present embodiment is substantially the same as the optical line loss measuring device described in the second embodiment, and a description of overlapping parts will be omitted.
[0065]
The optical line loss measuring device of the present embodiment is characterized in that the 1 × N optical switch 25 is provided between the optical pulse tester 1 and the optical coupler 6. Specifically, the optical pulse tester 1 is connected to the head 26 on one side of the 1 × N optical switch 25 via the communication light cutoff filter 18. Is connected to the c-ports of the plurality of optical couplers 6 inserted into the plurality of optical lines (for convenience, only one optical line system is shown in FIG. 8).
[0066]
The 1 × N optical switch 25 can be arbitrarily set by moving the one-core side head 26 to which the optical fiber from the optical pulse tester 1 is connected on a ball screw driven by a motor or the like in the longitudinal direction thereof. This is an optical switch for selecting the optical fiber on the N-core side. With the above configuration, the optical pulse tester 1 and the 1 × N optical switch 25 are remotely and automatically controlled, so that the loss measurement of all the optical lines is performed without reconnecting the optical pulse tester 1 for each test. be able to. In addition, not only the optical switch having the above configuration but also an optical switch using a thermo-optic effect, an optical switch using a micro machine technology called MEMS (Micro Electro Mechanical System), or the like is combined with an optical line loss measuring device. May be used.
[0067]
In the optical line loss measuring apparatus according to the present embodiment, particularly when testing an optical fiber cable having a large number of cores, it is not necessary to make a connection manually, so that the operation can be automated, and the operation time can be greatly reduced. , Work costs can be reduced.
[0068]
(Example 4)
FIG. 9 is a diagram illustrating Fresnel reflection and Fresnel secondary reflection in an optical line loss measuring device using a 4-port optical coupler.
[0069]
In the optical line loss measuring devices according to the first to third embodiments, the optical multiplexer / demultiplexer 27 having four optical input / output ports may be used instead of the optical multiplexer / demultiplexer 6 having three optical input / output ports. This is because an optical power meter 29 is attached to one port of the optical coupler 27 via a connector 28, and the light of the transmission device (in this case, the transmission device 17 is a measurement target in FIG. 11 described later). This is for measuring the output level.
[0070]
The optical multiplexer / demultiplexer 27 includes four 2 × 2 optical input / output ports (a, b, c, and d ports), and the ports a to b and d, or the ports c to b and d. The light is branched from port b to port a and port c, or from port d to port a and port c.
[0071]
However, in the optical line loss measuring device having the above configuration, when the optical power meter 29 is not connected to the connector 28 on the d port side of the optical multiplexer / demultiplexer 27, the test light from the optical pulse tester 1 is transmitted to the optical multiplexer / demultiplexer 27. Reflected by the connector 28 on the d-port side, and accurate measurement may not be possible. Specifically, when the connector 28 connected to the d port of the optical multiplexer / demultiplexer 27 is in the open state, the test light from the optical pulse tester 1 becomes large at the connector 28 on the d port side of the optical multiplexer / demultiplexer 27. The Fresnel reflection 30 (reflection from the connector 28) and the Fresnel secondary reflection 31 (reflection from the connector 28) of the path shown by the dotted line in FIG. From the light reflected from the
[0072]
FIG. 10 shows a graph of the OTDR waveform measured by the optical line loss measuring device shown in FIG.
As shown in FIG. 10, in the optical line loss measuring device having the above configuration, not only the Fresnel reflection 12 and the Fresnel secondary reflection 13 from the light reflector 2 but also the connector 28 and the light reflector 2 near the Fresnel reflection 12. , The Fresnel secondary reflection 31 is observed, and the Fresnel reflection 12 is affected by the Fresnel secondary reflection 31, so that accurate loss measurement may not be performed.
[0073]
Therefore, in this embodiment, when the optical power meter 29 is not used, the test light from the optical pulse tester 1 is attached by attaching the non-reflection terminal 32 to the connector 28 connected to the d port of the optical coupler 27. , Is prevented from being reflected at the d port of the optical coupler / shunter 27, thereby preventing correct measurement.
[0074]
FIG. 11 is a configuration diagram of a system in which a non-reflection termination is provided in the optical line loss measuring device shown in FIG. 9, and is another example of the embodiment of the optical line loss measuring device according to the present invention.
The configuration of the optical line loss measuring apparatus according to the present embodiment shown in FIG. 11 will be described. The optical line loss measuring apparatus is inserted and connected in the middle of an optical line to be measured (consisting of optical fibers 4, 5 and the like) to couple and split light. × 2 optical multiplexer / demultiplexer 27, an optical pulse tester 1 connected to the branch port (c port) of the optical multiplexer / demultiplexer 27 to measure the characteristics of the optical line, and another branch port (d Non-reflective termination 32 which is connected to the optical line and which does not reflect light, optical reflectors 14 and 15 which are connected to both ends of the optical line, and which are connected between the optical multiplexer / demultiplexer 27 and the optical pulse tester 1. And a communication light cutoff filter 18.
[0075]
(Example 5)
FIG. 12 is a configuration diagram of a system in which the 1 × N optical switch 33 is combined with the optical line loss measuring device shown in FIG. 9, and is another example of the embodiment of the optical line loss measuring device according to the present invention.
The optical line loss measuring device according to the present embodiment is substantially the same as the optical line loss measuring device shown in FIG.
[0076]
As shown in FIG. 12, in the optical line loss measuring apparatus according to the present embodiment, the optical pulse tester 1 is connected to the head 34 on one side of the 1 × N optical switch 33, and one on the N side is optically coupled and branched. The connector 28 connected to the port c of the optical coupler 27 and the connector 28 connected to the port d of the optical multiplexer / demultiplexer 27 are connected not to the non-reflective termination 32 but to the other one of the N-core side of the 1 × N optical switch 33. ing. A refractive index matching member 35 is provided inside the 1 × N optical switch 33, so that reflection at the d port of the optical coupler 27 can be reduced as in the non-reflection terminator 32.
[0077]
【The invention's effect】
According to the present invention, since the light reflector that reflects the test light is provided at both ends of the optical line, without being affected by the Fresnel reflection by the optical connector that is frequently used to connect the optical fibers constituting the optical line, Using an optical pulse tester, the optical loss of the optical path between the optical reflectors can be accurately determined by one measurement.
[0078]
Also, the optical reflector transmits the communication light of the transmission device and reflects and blocks the test light from the optical pulse tester, without affecting the optical communication service performed between the transmission devices. The optical loss of the optical line can be measured with high accuracy.
[0079]
Further, by using a 2 × 2 optical multiplexer / demultiplexer having four optical input / output ports and attaching an optical power meter to one of the branch ports of the optical multiplexer / demultiplexer, the output of the transmission device can be measured and When an optical power meter is not used, a non-reflective termination or a refractive index matching material may be attached instead to suppress the influence of reflection occurring at the branch port and measure the optical loss of the optical line accurately. it can.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an example (Example 1) of an embodiment of an optical line loss measuring device according to the present invention.
FIG. 2 is a diagram illustrating Fresnel reflection in the optical line loss measuring device shown in FIG.
FIG. 3 is a diagram illustrating Fresnel secondary reflection in the optical line loss measuring device shown in FIG. 1;
FIG. 4 is a graph of an OTDR waveform measured by the optical line loss measuring device shown in FIG.
FIG. 5 is a configuration diagram showing another example (Example 2) of the embodiment of the optical line loss measuring device according to the present invention.
6 is a schematic configuration diagram of an optical reflector in the optical line loss measuring device shown in FIG.
7 is a cross-sectional view of a specific configuration example of the light reflector shown in FIG.
8 shows another example (Example 3) of the embodiment of the optical line loss measuring device according to the present invention, and is a configuration diagram of a system in which an optical switch is combined with the optical line loss measuring device shown in FIG. 5; .
FIG. 9 is a diagram illustrating Fresnel reflection and Fresnel secondary reflection in an optical line loss measuring device using a four-port optical coupler.
10 is a graph of an OTDR waveform measured by the optical line loss measuring device shown in FIG.
11 shows another example (Example 4) of the embodiment of the optical line loss measuring device according to the present invention, and is a configuration diagram of a system in which a non-reflection termination is provided in the optical line loss measuring device shown in FIG. 9; is there.
12 shows another example (Example 5) of the embodiment of the optical line loss measuring device according to the present invention, and is a configuration diagram of a system in which an optical switch is combined with the optical line loss measuring device shown in FIG. 9; .
FIG. 13 is a configuration diagram illustrating an example of a conventional optical line loss measuring device.
14 is a graph of an OTDR waveform measured by the optical line loss measuring device shown in FIG.
FIG. 15 is a configuration diagram showing another example of the conventional optical line loss measuring device.
16 is a configuration diagram of a system in which an optical switch is combined with the optical line loss measuring device shown in FIG.
17 is a configuration diagram of a system in which an optical switch is combined with the optical line loss measuring device shown in FIG.
FIG. 18 is a diagram showing a realistic connection configuration of optical lines in a conventional optical line loss measuring device.
19 is a graph of an OTDR waveform measured by the optical line loss measuring device shown in FIG.
[Explanation of symbols]
1 Optical pulse tester
2 Light reflector
3 Light reflector
4 Optical fiber to be measured
5 Optical fiber
6 Optical coupler
7 Connector
8 Connector
9 Connector
10 fusion splicing points
11 Connector connection point

Claims (8)

Inserting and connecting an optical multiplexing / branching unit for multiplexing / branching light into an optical line made of an optical fiber,
An optical test unit for measuring characteristics of the optical line is connected to one of the branching sides of the optical coupling / branching unit,
A test light is incident on the optical line from the optical test means, and response light generated in the optical line by the test light is received by the optical test means, and a loss of the optical line is determined based on a waveform of the response light. In the optical line loss measuring method for measuring
Light reflecting means for reflecting the test light, connected to both ends of the optical line,
The known return loss of the one light reflecting means is defined as RLossB (dB),
When the known return loss of the other light reflecting means is RLossA (dB),
A level RB (dB) of a primary reflection of the one light reflecting means observed by the light testing means at a position of an end of the optical line;
A level RA (dB) of the secondary reflection of the one light reflection unit observed by the light test unit is measured at a position separated by the length of the optical line from the position where the primary reflection is measured. do it,
The optical loss FLoss (dB) of the optical line is
FLoss = RB + (RLossB / 2) -RA + (RLossA / 2)
An optical line loss measuring method characterized by being obtained from the following equation: The optical line loss measuring method according to claim 1,
Transmission means for transmitting and receiving communication light having a different wavelength from the test light is connected to each of the light reflection means at both ends,
While transmitting the test light, light blocking means for blocking the communication light, connected between the light testing means and the light branching means,
An optical line loss measuring method, wherein the light reflecting means transmits the communication light and reflects and blocks the test light. In the optical line loss measuring method according to claim 1 or 2,
The optical coupling / branching means has three 1 × 2 optical input / output ports,
Connecting the optical line to one of the two-port side and the one-port side of the optical coupling / branching means;
An optical line loss measuring method, comprising connecting the optical test means to the other of the two ports of the optical coupling / branching means. The optical line loss measuring device according to claim 1 or 2,
The optical coupling / branching means has four 2 × 2 optical input / output ports,
Connecting the optical line to one of the two port sides of the optical coupling / branching means and one of the other two port sides;
Connecting the optical test means to the other of the two ports of the optical coupling / branching means,
An optical line loss measuring method, characterized in that a non-reflection terminal or a refractive index matching material that does not reflect the test light is connected to the other of the two ports of the optical coupling / branching means. An optical multiplexing / branching unit that is inserted into and connected to an optical line made of an optical fiber, and multiplexes and branches light;
A test light is incident on the optical line, is connected to one of the branching sides of the optical coupling / branching unit, receives response light generated in the optical line by the test light, and receives the response light from the waveform of the response light. Light test means for measuring the characteristics of the road,
In the optical line loss measuring device for measuring the loss of the optical line,
It has light reflection means connected to both ends of the optical line and reflecting the test light,
The known return loss of the one light reflecting means is defined as RLossB (dB),
The known return loss of the other light reflection means is defined as RLosA (dB),
At the position of the end of the optical line, the level of primary reflection observed and measured by the optical test means is RB (dB),
The level of the secondary reflection of the one light reflecting unit, which is observed and measured by the optical testing unit, is set at a position separated by the length of the optical path from the position where the primary reflection is measured, by RA (dB). )
The optical loss FLoss (dB) of the optical line is:
FLoss = RB + (RLossB / 2) -RA + (RLossA / 2)
An optical line loss measuring device characterized by being obtained from the following equation: The optical line loss measuring device according to claim 5,
Transmission means connected to each of the light reflection means at both ends, transmitting and receiving communication light of a wavelength different from the test light,
A light blocking unit that is connected between the optical testing unit and the optical branching unit, transmits the test light, and blocks the communication light;
The optical line loss measuring device, wherein the light reflecting means transmits the communication light and reflects and blocks the test light. The optical line loss measuring device according to claim 5 or 6,
The optical coupling / branching unit has three 1 × 2 optical input / output ports,
The optical line is connected to one of the two-port side and the one-port side of the optical coupling / branching unit,
The optical line loss measuring device, wherein the optical test means is connected to the other of the two ports of the optical coupling / branching means. The optical line loss measuring device according to claim 1 or 2,
The optical coupling / branching unit has four 2 × 2 optical input / output ports,
The optical line is connected to one of the two-port side of the optical coupling / branching means and one of the other two-port side;
The optical test means is connected to the other of the two ports of the optical coupling / branching means,
An optical line loss measuring device, wherein a non-reflection terminal or a refractive index matching material that does not reflect the test light is connected to the other of the two ports of the optical coupling / branching means.

Images