JP4173967B2 - Optical fiber loss measuring method and measuring apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method and apparatus for measuring optical loss of an optical fiber line using an optical pulse tester (OTDR).
[0002]
[Prior art]
A conventional optical fiber loss measurement technique and its problems will be described with reference to FIGS.
[0003]
[First Conventional Example]
FIG. 14 shows a first conventional example of a measurement system that measures the optical loss of the optical fiber 5 to be measured using the optical pulse tester 1. In FIG. 14, an optical pulse tester 1 is connected to one end of an optical fiber 5, and an optical pulse (test light) is incident on the optical fiber 5. The optical pulse tester 1 receives response light with respect to an incident light pulse from the optical fiber 5 and measures the characteristics of the optical fiber 5 from the received response light waveform. When the optical fiber 5 is formed by connecting a plurality of optical fibers, there are fusion splice points 7 and connector connection points 8 in the middle. Reference numeral 11 denotes a connector provided at the far end e of the optical fiber 5.
[0004]
FIG. 15 shows an example of a response light waveform measured by the optical pulse tester 1 in the measurement system of FIG. In FIG. 15, the vertical axis represents the backscattered light level, and the horizontal axis represents the distance (the distance from the near end to the far end direction). From this response light waveform, when the backscattered light level at the near end s of the optical fiber 5 is X0 (dB) and the backscattered light level at the far end e is X1 (dB), it is far from the near end s of the optical fiber 5. The optical loss FLoss (dB) up to the end e is obtained by the following equation (1).
FLoss = X0-X1 (1)
The optical loss FLoss includes losses due to the fusion splicing point 7 and the connector connecting point 8 in the middle.
[0005]
[Second Conventional Example]
Next, as a second conventional example, FIG. 16 shows a measurement system for measuring the optical loss of the optical fiber 5 between the transmission device 20 and the transmission device 21 without affecting communication even during in-service. In FIG. 16, a test light blocking filter 23 and a test light blocking filter 33 having characteristics of blocking test light and transmitting communication light are inserted in front of the transmission device 20 and the transmission device 21, respectively. Further, a communication light blocking filter 25 having a characteristic of blocking the communication light and transmitting the test light is inserted in front of the optical pulse tester 1. Further, an optical coupler 22 is inserted into one end of the optical fiber 5. The optical pulse tester 1 is connected to the optical fiber 5 through the communication light blocking filter 25, the optical fiber 34, and the optical multiplexer / demultiplexer 22. The transmission device 20 is connected to the optical fiber 5 via the test light blocking filter 23, the optical fiber 24, and the optical multiplexer / demultiplexer 22. The transmission device 21 is connected to the optical fiber 5 via its test light blocking filter 33. In FIG. 16, 7 is a fusion splice point, 8 is a connector connection point, and 11 is a connector at the far end e of the optical fiber 5.
[0006]
In the measurement system of FIG. 16, by using light having a test wavelength (for example, 1650 nm) different from the communication wavelength (for example, 1310 nm) used between the transmission devices 20 and 21 as the test light of the optical pulse tester 1, It is possible to realize optical loss measurement of the optical fiber 5 without affecting communication.
[0007]
[Third conventional example]
Next, as a third conventional example, FIG. 17 shows a configuration example in which the optical loss of a plurality of optical fibers is measured by one optical pulse tester 1 using a 1 × N optical switch 28. In the measurement system of FIG. 17, a 1 × N optical switch 28 is inserted in the middle of the optical fiber 34 of FIG. 16. One core side of the 1 × N optical switch 28 is connected to the optical pulse tester 1, and N The core side is connected to the optical coupler 22. In FIG. 17, 7 is a fusion splicing point, 8 is a connector connection point, 20 and 21 are transmission devices, 23 and 33 are test light blocking filters, 24 is an optical fiber, 25 is a communication light blocking filter, and 29 is 1 × N. This represents the head (one core) of the optical switch.
[0008]
In the measurement system of FIG. 17, the optical pulse tester 1 is connected to a desired optical multiplexer / demultiplexer 22 by a 1 × N optical switch 28 to measure the optical loss of a plurality of optical fibers with one optical pulse tester 1. Is possible. Further, it is not necessary to manually attach the optical coupler / branch 22, the optical pulse tester 1, and the communication light blocking filter 25 for each measurement.
[0009]
The measurement system shown in FIG. 17 is introduced under the name of “Optical Test System” from p.111 to p.114 of “Actual Optical Access Network and π System (Telecommunications Association, 1999)”. Yes.
[0010]
[Fourth Conventional Example]
However, in an actual measurement system, as shown in FIG. 18, the optical pulse tester 1 and the optical fiber 5 to be measured are connected via a connector 9. Moreover, in the optical fiber 5, the connection point of the connector 10 on the way and the connection point of the connector 11 of a far end may be near. In the measurement system shown in FIG. 18, a connector 9 at the near end and a connector 10 approaching the far end are added to the measurement system in FIG.
[0011]
FIG. 19 shows an example of a response light waveform measured by the optical pulse tester 1 in the measurement system of FIG. In FIG. 19, the vertical axis represents the backscattered light level, and the horizontal axis represents the distance. As can be seen from this response light waveform, the backscattered light level at the near end cannot be accurately obtained by the Fresnel reflection 35 generated by the connector 9 at the near end. Further, the backscattered light level at the far end cannot be accurately obtained by the Fresnel reflection 36 generated by the connector 10 approaching the far end.
[0012]
Therefore, the optical loss of the optical fiber 5 cannot be measured accurately. This is a problem that also occurs in the measurement system shown in FIGS.
[0013]
[Problems to be solved by the invention]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide means for accurately measuring the optical loss of an optical fiber using an optical pulse tester.
[0017]
[Means for Solving the Problems]
The first invention is still another optical fiber loss measuring method, receiving an optical pulse from one end of the optical line and receiving response light composed of backscattered light and Fresnel reflected light generated in the optical line. In the optical fiber loss measurement method using the optical pulse tester for measuring the characteristics of the optical line from the response optical waveform, the A port, the B port, the C port, the D port, and four optical input / output ports are provided. The light is split from either the B port to the B port, or from the A port to the C port, and the light is split from the D port to the B port, or from the D port to the C port. A plurality of optical couplers each having a plurality of optical fibers to be measured connected to the C port, and a 2 × N optical switch, and one side of the optical fiber to be measured is connected to the C port of the optical coupler. The Subsequently, A port and B port of the plurality of optical couplers are connected in pairs to the N core side of the 2 × N optical switch, and the optical fiber to be measured is connected to the 2 core side of the 2 × N optical switch. Connect one end of the first optical fiber, which is different from And, The other end of the first optical fiber In Optical pulse tester The Connection As well as The first optical reflector is connected to the 2 core side of the 2 × N optical switch. By doing so, the optical pulse tester and the first optical reflector are arranged on the two core sides of the 2 × N optical switch so that the single first optical reflector can be shared by a plurality of optical fibers to be measured. Connected in pairs A second optical reflector is connected to the other end of the optical fiber to be measured, a second optical fiber different from the optical fiber to be measured is connected to the D port of the optical coupler, and the 2 × N The optical switch enables the optical pulse tester and the first optical reflector to be shared for all the optical couplers, and selects any one optical coupler from the plurality of optical couplers, The Fresnel reflection level RA (dB) from the first optical reflector and the Fresnel reflection level RB (dB) from the second optical reflector through any one optical multiplexer / demultiplexer and the 2 × N optical switch. Measured, the return loss of the first optical reflector is RLossA (dB), the return loss of the second optical reflector is RLossB (dB), and between the A port and the B port of any one optical multiplexer / demultiplexer. Loss of loss is Loss AB (dB), any one optical combiner When the loss between the A port and the C port is CLossAC (dB), and the connection loss of the 2 × N optical switch between the arbitrary one optical multiplexer / demultiplexer and the first optical reflector is WLoss (dB), The optical loss FLoss from the near end to the far end of the optical fiber to be measured is expressed as FLoss = (RLossA + (RA / 2) + LossAB + WLoss) − (RLossB + (RB / 2) + CLossAC)
It is characterized in that it is obtained by a single measurement from the equation (1).
[0018]
Second The invention First In the optical fiber loss measuring method of the invention, an optical reflector having a characteristic of transmitting the communication light and reflecting the test light, which is built in the far-end connector of the optical fiber to be measured, is used as the second optical reflector. It is characterized by using.
[0022]
The third invention is still another optical fiber loss measuring device, which receives an optical pulse from one end of an optical line and receives response light composed of backscattered light and Fresnel reflected light generated in the optical line. In the optical fiber loss measuring apparatus using the optical pulse tester for measuring the characteristics of the optical line from the response light waveform obtained, the optical pulse tester, the A port, the B port, the C port, the D port, and the four optical inputs It has an output port, and light is split into either the A port to the B port or from the A port to the C port, and either from the D port to the B port, or from the D port to the C port. In addition, the light can be split and split, and a plurality of optical couplers each having a plurality of optical fibers to be measured connected to the C port, and the A ports and B of the plurality of optical couplers on the N-core side. Port to pair 2 × N optical switches connected to each other, an optical fiber different from the optical fiber to be measured, which connects the optical pulse tester and the two cores of the 2 × N optical switch, and the 2 × N A first optical reflector connected to the two cores of the optical switch, and a second optical reflector connected to the other end of the optical fiber to be measured, The optical pulse tester and the first optical reflector are arranged on the two core sides of the 2 × N optical switch so that one optical reflector can be shared by a plurality of optical fibers to be measured. Connected and The 2 × N optical switch selects the optical pulse tester and the first optical reflector for all the optical couplers by selecting any one optical coupler from the plurality of optical couplers. The optical pulse tester is configured such that when the 2 × N optical switch selects any one optical multiplexer / demultiplexer from the plurality of optical couplers, the reflection attenuation of the first optical reflector is reduced. The amount of loss is RLossA (dB), the return loss of the second optical reflector is RLossB (dB), the loss between the A port and the B port of any one optical multiplexer / demultiplexer is CLossAB (dB), the arbitrary 1 The loss between the A port and the C port of one optical multiplexer / demultiplexer is CLossAC (dB), and the connection loss of the 2 × N optical switch between any one optical multiplexer / demultiplexer and the first optical reflector is WLoss (dB). The measurement object is connected to the D port of any one optical multiplexer / demultiplexer. In a state where a second optical fiber different from the optical fiber is connected, a level RA (dB) of Fresnel reflection from the first optical reflector measured through the arbitrary optical coupler, and the arbitrary 1 From the Fresnel reflection level RB (dB) from the second optical reflector measured through two optical couplers, the optical loss FLoss from the near end to the far end of the optical fiber to be measured is expressed as FLoss = (RLossA + ( RA / 2) + CLOSAB + WLoss)-(RLossB + (RB / 2) + CLossAC)
It is characterized in that it is obtained by a single measurement from the equation (1).
[0023]
4th The invention Third In the optical fiber loss measuring apparatus of the invention, the second optical reflector has a characteristic of transmitting communication light and reflecting test light, and is built in a connector at a far end of the optical fiber to be measured. And
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0025]
[First Example: Example using 1 × 2 optical switch]
A first embodiment of the present invention will be described with reference to FIGS.
[0026]
First, the measurement system of the first embodiment will be described. In FIG. 1, 1 is an optical pulse tester, 2 is a 1 × 2 optical switch (1 × 2 configuration optical switch), 3 is an optical fiber, 4 is an optical reflector (first optical reflector), and 5 is an optical fiber. (Measurement object), 6 represents a light reflector (second light reflector). 7 is a fusion splice point, 8 is a connector connection point, 9 is a connector at the near end s, 10 is a connector approaching the far end e, and 11 is a connector at the far end e.
[0027]
The optical pulse tester 1 receives an optical pulse from one end of the optical line, receives response light composed of backscattered light and Fresnel reflected light generated in the optical line, and determines the characteristics of the optical line from the received response light waveform. It is a device to measure.
[0028]
The 1 × 2 optical switch 2 includes an A port, a B port, and a C port and three optical input / output ports, and the optical path can be switched from the A port to the B port or from the A port to the C port. It is a possible optical switch.
[0029]
One end of the optical fiber 3 is connected to the A port of the 1 × 2 optical switch 2, and the optical pulse tester 1 is connected to the other end of the optical fiber 3. An optical reflector 4 is connected to the B port of the 1 × 2 optical switch 2, and an optical fiber 5 to be measured is connected to the C port of the 1 × 2 optical switch 2. Further, an optical reflector 6 is detachably connected to the opposite side of the optical fiber 5.
[0030]
The C port of the 1 × 2 optical switch 2 and the optical fiber 5 are connected via a connector 9.
[0031]
Accordingly, the 1 × 2 optical switch 2 has a function of inserting a light pulse (test light) from the optical pulse tester 1 into the optical fiber 5 and a function of measuring the reflected light from the light reflector 4. In the first embodiment, the light reflector 6 is manually attached to the connector 11 every measurement and is removed after the measurement.
[0032]
Next, the measurement method in the first embodiment will be described.
[0033]
(1) First, the 1 × 2 optical switch 2 is connected from the A port to the B port, and an optical pulse is emitted from the optical pulse tester 1 through the optical fiber 3 to the 1 × 2 optical switch 2. The level of Fresnel reflected light from the optical pulse tester 1 is measured.
[0034]
(2) Next, the 1 × 2 optical switch 2 is connected from the A port to the C port, and an optical pulse is emitted from the optical pulse tester 1 through the optical fiber 3 to the 1 × 2 optical switch 2. The level of Fresnel reflected light from 6 is measured by the optical pulse tester 1.
[0035]
However, the above measurement order of the level of the Fresnel reflected light from the light reflector 4 and the level of the Fresnel reflected light from the light reflector 6 is one example, and is not limited to this, and may be measured in the reverse order. good.
[0036]
FIG. 2 shows an example of a response light waveform measured by the above method. In FIG. 2, the vertical axis represents the backscattered light level, and the horizontal axis represents the distance. Originally, since the Fresnel reflection 12 from the light reflector 4 and the Fresnel reflection 13 from the light reflector 6 cannot be measured at one time, they do not appear on the same screen of the optical pulse tester 1. In order to simplify the explanation, explanation will be given on the same screen.
[0037]
The return loss of the optical reflector 4 is RLossA (dB), the return loss of the optical reflector 6 is RLossB (dB), and the loss between the A port and the B port of the 1 × 2 optical switch 2 is SLossAB (dB). The loss between the A port and the C port of the 1 × 2 optical switch 2 is S Loss AC (dB), the reflection level of the optical reflector 4 measured by the optical pulse tester 1 is RA (dB), and measured by the optical pulse tester 1 When the reflection level of the reflector 6 is RB (dB), if the optical loss from the near end s to the far end e of the optical fiber 5 is FLoss, the optical loss FLoss is obtained by the following equation (2). Measure with.
FLoss = (RLossA + ( RA / 2 ) + SLossAB)
-(RLossB + ( RB / 2 ) + SLossAC) (2)
[0038]
The optical loss FLoss includes losses due to the fusion splice point 7, connector connection point 8, connector 9 connection point, connector 10 connection point, and connector 11 connection point.
[0039]
According to the first embodiment, it is possible to avoid a decrease in measurement accuracy of the optical loss FLoss due to the influence on the backscattered light level at both ends of the optical fiber 5 due to Fresnel reflection. That is, the optical loss FLoss can be measured with high accuracy.
[0040]
The return loss RLossA of the optical reflector 4, the return loss RLossB of the optical reflector 6, and the loss SLossAB and SLossAC of each port of the 1 × 2 optical switch 2 are measured in advance. That is, the calculation of Expression (2) is performed with these as known losses.
[0041]
Here, the reflection of the light reflector 4 and the light reflector 6 is caused by the amount of Fresnel reflection generated by another connector, for example, the connector 9 at the near end s of the optical fiber 5 or the connector 11 at the far end e of the optical fiber 5. Need to be big enough. Accordingly, the optical loss FLoss can be accurately measured when the reflection attenuation amount of the light reflector 4 and the reflection attenuation amount of the light reflector 6 are close to complete reflection, such as 0 to 1 dB.
[0042]
The calculation for obtaining the optical loss FLoss by the equation (2) is performed by the optical pulse tester 1. This calculation may be performed by calculation means different from the optical pulse tester 1, but is equivalent to the calculation by the optical pulse tester 1.
[0043]
[Second embodiment: Example using an optical multiplexer / demultiplexer]
Next, a second embodiment of the present invention will be described with reference to FIGS. In the second embodiment, the 1 × 2 optical switch 2 used in the first embodiment is replaced with an optical multiplexer / demultiplexer 14, and the other components are the same, so the same members as in the first embodiment are the same. A reference numeral is attached, and duplicate description is omitted.
[0044]
First, the measurement system of the second embodiment will be described. In FIG. 2, 1 is an optical pulse tester, 14 is an optical multiplexer / demultiplexer having three optical input / output ports, 3 is an optical fiber, 4 is an optical reflector (first optical reflector), and 5 is an optical fiber (measurement). (Object), 6 represents a light reflector (second light reflector). Reference numeral 7 is a fusion splice point, 8 is a connector connection point, 9 is a near end connector, 10 is a connector close to the far end, and 11 is a far end connector.
[0045]
The optical combiner / branch unit 14 includes an A port, a B port, and a C port, and three optical input / output ports. It is a waver.
[0046]
Therefore, in the optical combiner / branch 14, light incident from the A port is emitted to both the B port and the C port. Conversely, both the light incident from the B port and the light incident from the C port are emitted to the A port.
[0047]
One end of the optical fiber 3 is connected to the A port of the optical coupler 14 and the optical pulse tester 1 is connected to the other end of the optical fiber 3. The optical reflector 4 is connected to the B port of the optical combiner / branch 14, and the optical fiber 5 to be measured is connected to the C port. Further, an optical reflector 6 is detachably connected to the opposite side of the optical fiber 5.
[0048]
The C port of the optical combiner / branch 14 and the optical fiber 5 are connected via a connector 9 as in the first embodiment.
[0049]
As a result, the optical multiplexer / demultiplexer 14 has a function of inserting the optical pulse (test light) from the optical pulse tester 1 into the optical fiber 5 and a function of measuring the reflected light from the optical reflector 4. The light reflector 6 is manually attached to the far-end connector 11 for each measurement and removed after the measurement.
[0050]
Next, the measurement method in the second embodiment will be described.
[0051]
In the second embodiment, a light pulse is emitted from the light pulse tester 1 through the optical fiber 3 to the optical combiner / branch 14, and the level of the Fresnel reflected light from the light reflector 4 and the Fresnel from the light reflector 6. The level of the reflected light is measured by the optical pulse tester 1.
[0052]
FIG. 4 shows an example of a response light waveform measured by the above method. In FIG. 4, the vertical axis represents the backscattered light level, the horizontal axis represents the distance, 12 represents Fresnel reflection from the light reflector 4, and 13 represents Fresnel reflection from the light reflector 6.
[0053]
The return loss of the optical reflector 4 is RLossA (dB), the return loss of the optical reflector 6 is RLossB (dB), the loss between the A port and the B port of the optical coupler 14 is CLossAB (dB), The loss between the A port and the C port of the branching device 14 is CLossAC (dB), the reflection level of the optical reflector 4 measured by the optical pulse tester 1 is RA (dB), and the reflector 6 measured by the optical pulse tester 1 When the reflection level is RB (dB), the optical loss FLoss from the near end to the far end of the optical fiber 5 is measured by the following equation (3).
FLoss = (RLossA + ( RA / 2 ) + CLossAB)
-(RLossB + ( RB / 2 ) + CLossAC) (3)
[0054]
According to the second embodiment, similarly to the first embodiment, it is possible to avoid a decrease in measurement accuracy of the optical loss FLoss due to the influence of the backscattered light level at both ends of the optical fiber 5 due to Fresnel reflection. That is, the optical loss FLoss can be measured with high accuracy. When the optical coupler 14 is connected to the optical fiber 5, the optical loss of the optical fiber 5 can be measured by one measurement.
[0055]
As in the first embodiment, the return loss RLossA of the light reflector 4, the return loss RLossB of the light reflector 6, and the loss CLossAB and LossAC of each port of the optical coupler 14 are measured in advance.
[0056]
As in the first embodiment, the reflection of the light reflector 4 and the reflection of the light reflector 6 are generated by other connectors, for example, the connector 9 at the near end of the optical fiber 5 and the connector 11 at the far end. It must be sufficiently larger than the amount of reflection. Therefore, the optical loss FLoss can be accurately measured when the reflection attenuation amount of the light reflector 4 and the light reflector 6 is close to complete reflection, such as 0 to 1 dB.
[0057]
Further, the optical pulse tester 1 performs the calculation for obtaining the optical loss FLoss by the equation (3). This calculation may be performed by calculation means different from the optical pulse tester 1, but is equivalent to the calculation by the optical pulse tester 1.
[0058]
[Third embodiment]
Next, a third embodiment of the present invention will be described with reference to FIGS.
[0059]
[Third embodiment 1: Connector with reflector]
In the third embodiment, as the second light reflector, as shown in FIG. 5, a light reflector having such characteristics that the communication light 15 is transmitted and the test light 16 is reflected so as not to affect the optical communication. 6a is used. The light reflector 6a is built in the far end connector. Hereinafter, the far-end connector incorporating the light reflector 6a is referred to as a reflector-equipped connector 11a.
[0060]
6 and 7 show a specific configuration example of the reflector-equipped connector 11a. The reflector-equipped connector 11 a shown in FIG. 6 is obtained by embedding a dielectric multilayer filter 18 in an SC connector ferrule 17. The reflector-equipped connector 11 a shown in FIG. 7 is obtained by embedding a fiber grating filter 19 in the SC connector ferrule 17.
[0061]
In the first and second embodiments described above, it is necessary to attach the light reflector 6 to the far-end connector 11 for each measurement. However, in the third embodiment, the connector 11a with a reflector is the light reflector. Since the connector 6a is built in in advance, the connector 11a with a reflector is attached to the end of the optical fiber 5 in advance as a far-end connector, so that the light reflector 6 is manually attached to the connector 11 every measurement. No need for work.
[0062]
In the first and second embodiments described above, the light reflector 6 that is not incorporated in the connector 11 itself has a characteristic of transmitting the communication light and reflecting the test light, and does not affect the optical communication. It may be.
[0063]
[Third embodiment 2: Example using a 1 × 2 optical switch and a connector with a reflector]
Next, referring to FIG. 8, in the configuration of the first embodiment (FIG. 1), the optical fiber can be used without actually affecting the communication between the transmission device 20 and the transmission device 21 using the connector 11a with a reflector. The system configuration for measuring the optical loss of 5 will be described. Therefore, the same members as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0064]
In FIG. 8, 1 is an optical pulse tester, 2 is a 1 × 2 optical switch, 3 is an optical fiber (another optical fiber), 4 is an optical reflector (first optical reflector), and 5 is an optical fiber (measurement object). ), 7 is a fusion splice point, 8 is a connector connection point, 9 is a connector at the near end, 10 is a connector near the far end, 11a is a connector with a reflector at the far end (built-in light reflector 6a), 20 is A transmission device, 21 is a transmission device, 22 is an optical coupler, 23 is a test light blocking filter, 24 is an optical fiber (second optical fiber), 25 is a communication light blocking filter, 26 is a connector, and 27 is an optical fiber.
[0065]
As described with reference to FIGS. 5 to 7 (third embodiment 1), the reflector-equipped connector 11a includes a light reflector (second light reflector) 6a that transmits communication light and reflects test light. Which is attached to the end of the optical fiber 5 in advance.
[0066]
The optical multiplexer / demultiplexer 22 is an optical multiplexer / demultiplexer for connecting and disconnecting the optical fiber 5 to and from the optical fiber 24 for connection to the transmission device 20 and the optical fiber 27 for connection to the 1 × 2 optical switch 2. The fiber 5 is connected by a connector 9.
[0067]
The test light blocking filter 23 is a filter having a characteristic of blocking test light and transmitting communication light. The communication light blocking filter 25 is a filter having a characteristic of blocking communication light and transmitting test light.
[0068]
Before measuring the optical loss of the optical fiber 5 between the transmission device 20 and the transmission device 21, the optical coupler 22 is inserted between the optical fiber 5 and the optical fiber 24. Further, the test light blocking filter 23 is inserted in front of the transmission device 21, and the reflector-equipped connector 11 a is inserted in front of the transmission device 21. Further, a communication light blocking filter 25 is inserted in front of the optical pulse tester 1.
[0069]
The optical coupler / branch 22, the test light blocking filter 23, the reflector-equipped connector 11a, and the communication light blocking filter 25 are normally inserted at all times.
[0070]
According to the first embodiment, one end of the optical fiber 3 is connected to the A port of the 1 × 2 optical switch 2. The optical pulse tester 1 is connected to the other end of the optical fiber 3 via a communication light blocking filter 25. The light reflector 4 is connected to the B port of the 1 × 2 optical switch 2.
[0071]
The optical fiber 5 to be measured is connected to the C port of the 1 × 2 optical switch 2 by connecting the optical coupler 22 via the optical fiber 27 with the connector 26.
[0072]
Thereby, the optical multiplexer / demultiplexer 22 has a function of inserting the optical pulse (test light) from the optical pulse tester 1 into the optical fiber 5. The 1 × 2 optical switch 2 has a function of measuring the reflected light from the optical reflector 4 and inserts the optical pulse (test light) from the optical pulse tester 1 into the optical fiber 5 via the optical coupler / brancher 22. It has a function.
[0073]
The measurement method in this example is the same as that in the first example. For example,
(1) The 1 × 2 optical switch 2 is connected from the A port to the B port, and an optical pulse is emitted from the optical pulse tester 1 through the optical fiber 3 to the 1 × 2 optical switch 2. The level of the Fresnel reflected light is measured by the optical pulse tester 1.
(2) Next, the 1 × 2 optical switch 2 is connected from the A port to the C port, and an optical pulse is emitted from the optical pulse tester 1 through the optical fiber 3 to the 1 × 2 optical switch 2 with a reflector. The level of Fresnel reflected light from the light reflector 6 a of the connector 11 a is measured by the optical pulse tester 1.
[0074]
Similarly to the first embodiment, the return loss of the light reflector 4 is RLossA (dB), the return loss of the light reflector 6a is RLossB (dB), and between the A port and the B port of the 1 × 2 optical switch 2 The loss between the A port and the C port of the 1 × 2 optical switch 2 is S Loss AC (dB), the reflection level of the optical reflector 4 measured by the optical pulse tester 1 is RA (dB), When the reflection level of the reflector 6a measured by the optical pulse tester 1 is RB (dB), the optical loss FLoss from the near end to the far end of the optical fiber 5 is obtained by the above equation (2). I do.
[0075]
Accordingly, by making the test light wavelength from the optical pulse tester 1 different from the communication light wavelength used between the transmission devices 20 and 21, communication is affected even during communication between the transmission devices 20 and 21. The optical loss FLoss of the optical fiber 5 can be accurately measured without giving That is, since the optical reflector 6a is built in the connector 11a at the far end of the optical fiber 5 in advance, the communication during the optical communication of the working optical fiber 5 is not affected.
[0076]
Here, the reflection of the light reflector 4 and the reflection of the light reflector 6a need to be sufficiently larger than the amount of Fresnel reflection generated in the other connector, for example, the connector 9 at the near end of the optical fiber 5 or the connector 11a at the far end. There is. Therefore, the optical loss FLoss can be measured with higher accuracy when the reflection loss of the light reflector 4 and the reflection attenuation of the light reflector 6a built in the connector 11a are close to perfect reflection, such as 0 to 1 dB.
[0077]
In this example, by connecting the 1 × 2 optical switch 2 to the optical coupler / branch 22 using the connector 26, the optical pulse tester 1, the optical fiber 3, and the 1 × 2 optical switch are measured every time the optical loss is measured. 2 and the light reflector 4 are attached to the optical fiber 5. However, the 1 × 2 optical switch 2 may be connected to the optical coupler 22 at all times.
[0078]
[Third embodiment 3: Example using a 1 × 2 optical switch, a connector with a reflector, and a 1 × N optical switch]
Next, referring to FIG. 9, in the configuration of the first embodiment (FIG. 1), the connector 11a with reflector and the 1 × N optical switch 28 are used to actually affect the communication between the transmission device 20 and the transmission device 21. The system configuration for measuring the optical loss of the optical fiber 5 without giving the above will be described. This example is different from the example of FIG. 8 (third embodiment part 2) in that a 1 × N optical switch 28 is inserted between the 1 × 2 optical switch 2 and the optical coupler 22. Since the configuration of is the same, the same members as those in the example of FIG.
[0079]
In FIG. 9, 1 is an optical pulse tester, 2 is a 1 × 2 optical switch, 3 is an optical fiber (another optical fiber), 4 is an optical reflector (first optical reflector), and 5 is an optical fiber (measurement object). 7 is a fusion splice point, 8 is a connector connection point, 9 is a connector at the near end, 10 is a connector close to the far end, 11a is a connector with a reflector at the far end, 20 is a transmission device, and 21 is a transmission device. , 22 is an optical coupler, 23 is a test light blocking filter, 24 is an optical fiber (second optical fiber), 25 is a communication light blocking filter, 26 is a connector, 27 is an optical fiber, and 28 is a 1 × N optical switch (1 , An optical switch of × N configuration, 29 represents a single-core head.
[0080]
The optical multiplexer / demultiplexer 22 is an optical multiplexer / demultiplexer for coupling and connecting the optical fiber 5 to the optical fiber 24 for connection to the transmission device 20 and the optical fiber 27 for connection to the 1 × 2 optical switch 2. 5 is connected by a connector 9 at the near end.
[0081]
In FIG. 9, only one set of the optical fiber 5 and the optical coupler / branch 22 is shown. However, when there are a plurality of communication systems including the transmission apparatuses 20 and 21 and the optical fiber 5 between them, the optical fiber 5 and the optical coupler 22 are shown in FIG. Similarly, an optical multiplexer / demultiplexer 22 is connected.
[0082]
A plurality of optical combiners / branches 22 are connected in advance via optical fibers 27 to the N-core side of the 1 × N optical switch 28 in advance. A connector 26 of the C port of the 1 × 2 optical switch 2 is connected to one core side of the 1 × N optical switch 28 in advance.
[0083]
Therefore, a desired optical multiplexer / demultiplexer 22 is selected and connected to the C port of the 1 × 2 optical switch 2 according to the operation of the head 29 of the 1 × N optical switch 28, and as a result, the desired optical fiber 5 is selected. Are connected as measurement targets.
[0084]
As in the example of FIG. 8, one end of the optical fiber 3 is connected to the A port of the 1 × 2 optical switch 2. The optical pulse tester 1 is connected to the other end of the optical fiber 3 via a communication light blocking filter 25. An optical reflector 4 is connected to the B port of the 1 × 2 optical switch 2.
[0085]
Next, the measurement method in this example will be described.
[0086]
(1) For example, the 1 × 2 optical switch 2 is connected from the A port to the B port, and an optical pulse is emitted from the optical pulse tester 1 through the optical fiber 3 to the 1 × 2 optical switch 2. The level of Fresnel reflected light from the optical pulse tester 1 is measured.
[0087]
(2) Next, the 1 × 2 optical switch 2 is connected from the A port to the C port, the desired optical combiner / branch 22 is selected by the 1 × N optical switch 28, and the optical pulse tester 1 to the optical fiber 3 An optical pulse is emitted to a desired optical fiber 5 via the 1 × 2 optical switch 2, 1 × N optical switch 28 and the optical coupler / branch 22, and the Fresnel reflected light from the optical reflector 6 a of the connector 11 a with a reflector is transmitted. The level is measured with an optical pulse tester 1. However, the test light wavelength is different from the communication light wavelength.
[0088]
As in the example of FIG. 8, the reflection loss amount of the optical reflector 4 is RLossA (dB), the reflection attenuation amount of the optical reflector 6a is RLossB (dB), and between the A port and the B port of the 1 × 2 optical switch 2 The loss between the A port and the C port of the 1 × 2 optical switch 2 is S Loss AC (dB), the reflection level of the optical reflector 4 measured by the optical pulse tester 1 is RA (dB), When the reflection level of the reflector 6a measured by the optical pulse tester 1 is RB (dB), assuming that the optical loss from the near end to the far end of the optical fiber 5 is FLoss, the optical loss is calculated by the above equation (2). Measurement is performed by obtaining FLoss.
[0089]
In this example, since the 1 × N optical switch 28 is provided, the 1 × N optical switch 28, the 1 × 2 optical switch 2 and the optical pulse tester 1 are controlled remotely and automatically, as shown in FIG. In contrast to this, it is not necessary to attach the optical pulse tester 1, the optical fiber 3, the 1 × 2 optical switch 2, and the optical reflector 4 to the optical fiber 5 every time the optical loss is measured.
[0090]
Further, in this example, by using the 1 × N optical switch 28, one optical reflector 4 can be shared for optical loss measurement of a plurality of optical fibers 5, and the optical loss is measured economically and at a high density. System can be constructed.
[0091]
[Third embodiment part 4: measurement using optical coupler and connector with reflector]
Next, referring to FIG. 10, in the configuration of the second embodiment (FIG. 3), the optical fiber is used without actually affecting the communication between the transmission device 20 and the transmission device 21 by using the connector with reflector 11a. The system configuration for measuring the optical loss of 5 will be described. In other words, this example is different from the example of FIG. 8 (third embodiment part 2) in that an optical multiplexer / demultiplexer 14 is used instead of the 1 × 2 optical switch 2 and the other configurations are the same. The same members as those in the example of FIG. 8 or the second embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0092]
In FIG. 10, 1 is an optical pulse tester, 14 is an optical multiplexer / demultiplexer, 3 is an optical fiber (another optical fiber), 4 is an optical reflector (first optical reflector), 5 is an optical fiber (measurement object), 7 is a fusion splice point, 8 is a connector connection point, 9 is a connector at the near end, 10 is a connector near the far end, 11a is a connector with a reflector at the far end, 20 is a transmission device, 21 is a transmission device, and 22 is An optical coupler, 23 is a test light blocking filter, 24 is an optical fiber (second optical fiber), 25 is a communication light blocking filter, 26 is a connector, and 27 is an optical fiber.
[0093]
As described with reference to FIG. 5, the reflector-equipped connector 11 a is a connector that incorporates an optical reflector (second optical reflector) 6 a that transmits communication light and reflects test light. It is attached.
[0094]
The optical combiner / branch unit 14 includes an A port, a B port, and a C port, and three optical input / output ports, and light is multiplexed / divided either from the A port to the B port or from the A port to the C port. This is an optical coupler.
[0095]
The optical multiplexer / demultiplexer 22 is an optical multiplexer / demultiplexer for coupling and branching the optical fiber 5 to the connection optical fiber 24 on the transmission device 20 side and the connection optical fiber 27 on the optical multiplexer / demultiplexer 14 side. Are connected by a connector 9. The optical fiber 27 is connected to the C port of the optical coupler 14 by a connector 26.
[0096]
Before measuring the optical loss of the optical fiber 5 between the transmission device 20 and the transmission device 21, the optical coupler 22 is inserted between the optical fiber 5 and the optical fiber 24. Further, the test light blocking filter 23 is inserted in front of the transmission device 21, and the reflector-equipped connector 11 a is inserted in front of the transmission device 21. Further, a communication light blocking filter 25 is inserted in front of the optical pulse tester 1.
[0097]
According to the second embodiment, one end of the optical fiber 3 is connected to the A port of the optical coupler / splitter 14. The optical pulse tester 1 is connected to the other end of the optical fiber 3 via a communication light blocking filter 25. The light reflector 4 is connected to the B port of the optical combiner / branch 14.
[0098]
The C port of the optical coupler 14 is connected to the optical coupler 22 via the connector 26 and the optical fiber 27. As a result, the optical fiber 5 to be measured is connected to the C port of the optical combiner / branch 14.
[0099]
Thereby, the optical multiplexer / demultiplexer 22 has a function of inserting the optical pulse (test light) from the optical pulse tester 1 into the optical fiber 5. The optical coupler 14 has a function of measuring the reflected light from the optical reflector 4 and a function of inserting the optical pulse (test light) from the optical pulse tester 1 into the optical fiber 5 through the optical coupler 22. Prepare.
[0100]
The measurement method in this example is the same as that in the second example, and an optical pulse is emitted from the optical pulse tester 1 through the optical fiber 3 to the optical combiner / branch 14 and the Fresnel reflected light from the optical reflector 4 is reflected. The level and the level of the Fresnel reflected light from the light reflector 6 a of the connector with reflector 11 a are measured by the optical pulse tester 1.
[0101]
The return loss of the optical reflector 4 is RLossA (dB), the return loss of the optical reflector 6a is RLossB (dB), the loss between the A port and the B port of the optical coupler 14 is CLossAB (dB), The loss between the A port and the C port of the branching unit 14 is CLossAC (dB), the reflection level of the optical reflector 4 measured by the optical pulse tester 1 is RA (dB), and the reflector 6a measured by the optical pulse tester 1 If the optical loss from the near end s to the far end e of the optical fiber 5 is defined as FLoss, the measurement is performed by obtaining the optical loss FLoss according to the above equation (3).
[0102]
Therefore, by making the test light wavelength from the optical pulse tester 1 different from the communication wavelength used between the transmission devices 20 and 21, communication is affected even during communication between the transmission devices 20 and 21. Without giving, the optical loss FLoss of the optical fiber 5 can be measured with high accuracy.
[0103]
In this example, by connecting the optical coupler / branch 14 to the optical coupler / branch 22 using the connector 26, the optical pulse tester 1, the optical fiber 3, the optical coupler / branch 14 and the light reflection are measured every time the optical loss is measured. The device 4 is attached to the optical fiber 5. However, the optical multiplexer / demultiplexer 14 may be connected to the optical multiplexer / demultiplexer 22 at all times.
[0104]
[Third Example 5: Measurement using an optical coupler / reflector connector and a 1 × N optical switch]
Next, referring to FIG. 11, in the configuration of the second embodiment (FIG. 3), the connector 11a with a reflector and the 1 × N optical switch 28 are used to actually affect the communication between the transmission device 20 and the transmission device 21. The system configuration for measuring the optical loss of the optical fiber 5 without giving the above will be described. In other words, this example differs from the example of FIG. 10 (third embodiment No. 4) in that a 1 × N optical switch 28 is inserted between the optical coupler 14 and the optical coupler 22. Since the other configurations are the same, the same members as those in the example of FIG. 10 or the second embodiment are denoted by the same reference numerals, and redundant description is omitted.
[0105]
In FIG. 11, 1 is an optical pulse tester, 14 is an optical multiplexer / demultiplexer, 3 is an optical fiber (another optical fiber), 4 is an optical reflector (first optical reflector), 5 is an optical fiber (measurement object), 7 is a fusion splice point, 8 is a connector connection point, 9 is a connector at the near end, 10 is a connector near the far end, 11a is a connector with a reflector at the far end, 20 is a transmission device, 21 is a transmission device, and 22 is Optical multiplexer / demultiplexer, 23 is a test light blocking filter, 24 is an optical fiber (second optical fiber), 25 is a communication light blocking filter, 26 is a connector, 27 is an optical fiber, 28 is a 1 × N optical switch, and 29 is one core. Represents the head.
[0106]
The optical multiplexer / demultiplexer 22 is an optical multiplexer / demultiplexer for branching the optical fiber 5 into the connecting optical fiber 24 on the transmission device 20 side and the connecting optical fiber 27 on the optical multiplexer / demultiplexer 14 side. The connection is made with the connector 9 at the near end.
[0107]
In FIG. 11, one set of the optical fiber 5 and the optical coupler 22 is shown. However, when there are a plurality of transmission systems including the transmission devices 20 and 21 and the optical fiber 5 therebetween, FIG. Similarly, an optical multiplexer / demultiplexer 22 is connected.
[0108]
A plurality of optical combiners / branches 22 are connected in advance via optical fibers 27 to the N-core side of the 1 × N optical switch 28 in advance. A connector 26 of the C port of the optical coupler 14 is connected to one core side of the 1 × N optical switch 28 in advance.
[0109]
Therefore, a desired optical coupler / branch 22 is selected and connected to the C port of the optical coupler / branch 14 according to the operation of the head 29 of the 1 × N optical switch 28, and as a result, the desired optical fiber 5 is measured. Connected as a target.
[0110]
As in the example of FIG. 10, one end of the optical fiber 3 is connected to the A port of the optical multiplexer / demultiplexer 14. The optical pulse tester 1 is connected to the other end of the optical fiber 3 via a communication light blocking filter 25. The light reflector 4 is connected to the B port of the optical combiner / branch 14.
[0111]
Next, the measurement method in this example will be described. In this example, after a desired optical coupler / branch 22 is selected by the 1 × N optical switch 28, an optical pulse is emitted from the optical pulse tester 1 to the optical coupler / branch 14 through the optical fiber 3 as in the example of FIG. Then, the level of the Fresnel reflected light from the light reflector 4 and the level of the Fresnel reflected light from the light reflector 6a of the connector with reflector 11a are measured by the optical pulse tester 1. The test light wavelength is different from the communication light wavelength.
[0112]
As in the example of FIG. 10, the return loss of the optical reflector 4 is RLossA (dB), the return loss of the optical reflector 6a is RLossB (dB), and the loss between the A port and the B port of the optical coupler 14 Is the loss AB (dB), the loss between the A port and the C port of the optical coupler 14 is the loss AC (dB), the reflection level of the optical reflector 4 measured by the optical pulse tester 1 is RA (dB), the optical pulse tester When the reflection level of the reflector 6a measured in 1 is RB (dB), if the optical loss from the near end to the far end of the optical fiber 5 is FLoss, the optical loss FLoss is obtained by the above equation (3). Measure with.
[0113]
In this example, since the 1 × N optical switch 28 is provided, by controlling the 1 × N optical switch 28 and the optical pulse tester 1 remotely and automatically, unlike in the example of FIG. There is no need to attach the optical pulse tester 1, the optical fiber 3, the optical multiplexer / demultiplexer 14, and the optical reflector 4 to the optical fiber 5.
[0114]
[Fourth embodiment: Measurement using an optical multiplexer / demultiplexer in which two optical couplers are integrated into one and a connector with a reflector]
Next, referring to FIG. 12, the two optical multiplexer / demultiplexers 14 and the optical multiplexer / demultiplexer 22 in the example of FIG. 10 (third embodiment No. 4) are integrated into one, and actually between the transmission apparatus 20 and the transmission apparatus 21. A system configuration for measuring the optical loss of the optical fiber 5 without affecting the communication will be described. In other words, the fourth embodiment is different from the example of FIG. 10 in that one optical combiner / branch 30 is used instead of the two optical combiners / branches 14 and 22, and the other configurations are the same. Therefore, the same members as those in the example of FIG. 10 are denoted by the same reference numerals, and redundant description is omitted.
[0115]
In FIG. 12, 1 is an optical pulse tester, 30 is an optical multiplexer / demultiplexer having four optical input / output ports, 3 is an optical fiber (another optical fiber), 4 is an optical reflector (first optical reflector), 5 Is an optical fiber (measurement object), 7 is a fusion splice point, 8 is a connector connection point, 9 is a connector at the near end, 10 is a connector near the far end, 11a is a connector with a reflector at the far end, and 20 is a transmission device. , 21 is a transmission device, 23 is a test light blocking filter, 24 is an optical fiber (second optical fiber), and 25 is a communication light blocking filter.
[0116]
The optical combiner / branch unit 30 includes four optical input / output ports including an A port, a B port, a C port, and a D port. Light incident from the A port is incident on both the B port and the C port, and light incident from the D port This is an optical component that emits to both the B port and the C port. Conversely, light incident from the B port is emitted to both the A port and the D port, and light incident from the C port is emitted to both the A port and the D port.
[0117]
The reflector-equipped connector 11a is attached to the end of the optical fiber 5, and incorporates a light reflector (second light reflector) 6a that transmits communication light and reflects test light.
[0118]
Before measuring the optical loss of the optical fiber 5 between the transmission device 20 and the transmission device 21, the optical multiplexer / demultiplexer 30 is inserted between the optical fiber 5 and the optical fiber 24. Further, the test light blocking filter 23 is inserted in front of the transmission device 21, and the reflector-equipped connector 11 a is inserted in front of the transmission device 21. Further, a communication light blocking filter 25 is inserted in front of the optical pulse tester 1.
[0119]
One end of the optical fiber 3 is connected to the A port of the optical coupler 30. The optical pulse tester 1 is connected to the other end of the optical fiber 3 via a communication light blocking filter 25. The light reflector 4 is connected to the B port of the optical combiner / branch 14.
[0120]
Further, the optical fiber 5 to be measured is connected to the C port of the optical coupler 30 via the connector 9. Further, the optical fiber 24 connected to the transmission device 20 is connected to the D port of the optical multiplexer / demultiplexer 30.
[0121]
As a result, the optical multiplexer / demultiplexer 30 has an integrated function of inserting a light pulse (test light) from the optical pulse tester 1 into the optical fiber 5 and a function of measuring the reflected light from the light reflector 4.
[0122]
The measurement method in the fourth embodiment is the same as in the example of FIG. 10 (third embodiment No. 4), and an optical pulse is sent from the optical pulse tester 1 to the A port of the optical multiplexer / demultiplexer 30 via the optical fiber 3. , And the level of the Fresnel reflected light from the light reflector 4 and the level of the Fresnel reflected light from the light reflector 6a of the reflector-equipped connector 11a are measured by the optical pulse tester 1.
[0123]
The return loss of the optical reflector 4 is RLossA (dB), the return loss of the optical reflector 6a is RLossB (dB), the loss between the A port and the B port of the optical combiner / branch 30 is CLossAB (dB). The loss between the A port and the C port of the branching device 30 is CLossAC (dB), the reflection level of the optical reflector 4 measured by the optical pulse tester 1 is RA (dB), and the reflector 6a measured by the optical pulse tester 1 When the reflection level is RB (dB), assuming that the optical loss from the near end to the far end of the optical fiber 5 is FLoss, the measurement is performed by obtaining the light loss FLoss by the above equation (3).
[0124]
Therefore, instead of the two optical couplers 14 and 22 in the example of FIG. 10 (third embodiment No. 4), an optical pulse tester is obtained by using one optical multiplexer / demultiplexer 30 integrating them. By making the test light wavelength from 1 different from the communication wavelength used between the transmission devices 20 and 21, the optical fiber can be used without affecting the communication even during the communication between the transmission devices 20 and 21. 5 can be measured with high accuracy.
[0125]
Here, when the communication method between the transmission apparatuses 20 and 21 adopts a method in which the influence on the reflection of the transmission line is weak, the light reflector 4 reflects the test light wavelength (for example, 1650 nm). For the communication light wavelength (for example, 1310 nm), a light reflector designed to suppress reflection is used.
[0126]
[Fifth embodiment: measurement using an optical multiplexer / demultiplexer in which two optical couplers are integrated into one, a connector with a reflector, and a 2 × N optical switch]
Next, referring to FIG. 13, the 2 × N optical switch 31 is used in the configuration of the fourth embodiment (FIG. 12), and the optical communication is performed without actually affecting the communication between the transmission device 20 and the transmission device 21. A system configuration for measuring the optical loss of the fiber 5 will be described. That is, in the fifth embodiment, 2 × N light is provided between the A port of the optical coupler 30 and the optical fiber 3 and between the B port and the optical reflector 4 as compared with the fourth embodiment. Since the switch 31 is inserted and the other configurations are the same, the same members as those in the fourth embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0127]
In FIG. 13, 1 is an optical pulse tester, 30 is an optical multiplexer / demultiplexer, 3 is an optical fiber (another optical fiber or first optical fiber), 4 is an optical reflector (first optical reflector), and 5 is an optical fiber. (Measurement target), 7 is a fusion splice point, 8 is a connector connection point, 9 is a connector at the near end, 10 is a connector near the far end, 11a is a connector with a reflector at the far end, 20 is a transmission device, 21 is Transmission device, 23 is a test light blocking filter, 24 is an optical fiber (second optical fiber), 25 is a communication light blocking filter, 31 is a 2 × N optical switch (2 × N configuration optical switch), and 32 is a 2-core Represents the head.
[0128]
Although FIG. 13 shows one set of the optical fiber 5 and the optical coupler 30, when there are a plurality of communication systems including the transmission devices 20 and 21 and the optical fiber 5 between them, FIG. Similarly, an optical multiplexer / demultiplexer 30 is connected.
[0129]
On the N-core side of the 2 × N optical switch 30, the A port and the B port of the plurality of optical couplers 30 are previously paired and connected via optical fibers. The optical fiber 3 and the optical reflector 4 are previously connected to the two cores of the 2 × N optical switch 31 in advance. The optical fiber 3 corresponds to the A port of the optical coupler 30 and the optical reflector 4 corresponds to the B port.
[0130]
Therefore, a desired optical coupler 30 is selected according to the operation of the head 32 of the 2 × N optical switch 31. The optical pulse tester 1 is connected to the A port of the selected optical multiplexer / demultiplexer 30 via the 2 × N optical switch 31 and the optical fiber 3, and the optical reflection is made to the B port via the 2 × N optical switch 31. A device 4 is connected. The optical fiber 5 connected to the C port of the selected optical multiplexer / demultiplexer 30 via the connector 9 is a measurement target.
[0131]
The reflector-equipped connector 11a is attached to the end of the optical fiber 5, and incorporates a light reflector (second light reflector) 6a that transmits communication light and reflects test light.
[0132]
Before measuring the optical loss of the optical fiber 5 between the transmission device 20 and the transmission device 21, the optical multiplexer / demultiplexer 30 is inserted between the optical fiber 5 and the optical fiber 24. Further, the test light blocking filter 23 is inserted in front of the transmission device 21, and the reflector-equipped connector 11 a is inserted in front of the transmission device 21. Further, a communication light blocking filter 25 is inserted in front of the optical pulse tester 1.
[0133]
Next, the measurement method in the fifth embodiment will be described.
[0134]
In the fifth embodiment, after a desired optical coupler / branch 30 is selected by the 2 × N optical switch 30, the optical coupler / branch 30 A is connected from the optical pulse tester 1 through the optical fiber 3 as in the fourth embodiment. An optical pulse is emitted to the port, and the level of the Fresnel reflected light from the optical reflector 4 and the level of the Fresnel reflected light from the optical reflector 6a of the connector with reflector 11a are measured by the optical pulse tester 1. The test light wavelength is different from the communication light wavelength.
[0135]
In the fifth embodiment, the optical loss FLoss from the near end to the far end of the optical fiber 5 is considered in consideration of the connection loss WLoss of the 2 × N optical switch 30 between the optical coupler 30 and the optical reflector 4. Ask.
[0136]
That is, the return loss of the optical reflector 4 is RLossA (dB), the return loss of the optical reflector 6a is RLossB (dB), the loss between the A port and the B port of the optical combiner / branch 30 is CLossAB (dB), The loss between the A port and the C port of the splitter 30 is CLossAC (dB), the connection loss of the 2 × N optical switch 30 between the optical coupler 30 and the optical reflector 4 is WLoss (dB), and an optical pulse tester. When the reflection level of the optical reflector 4 measured in 1 is RA (dB) and the reflection level of the reflector 6a measured in the optical pulse tester 1 is RB (dB), from the near end to the far end of the optical fiber 5 The optical loss FLoss is measured by the following equation (4).
FLoss = (RLossA + ( RA / 2 ) + CLossAB + WLoss)
-(RLossB + ( RB / 2 ) + CLossAC) (4)
[0137]
The loss WLoss in the equation (4) is measured in advance as in RLossA, RLossB, LossAB, and LossAC.
[0138]
In the fifth embodiment, since the 2 × N optical switch 28 is provided, one optical reflector 4 can be shared for the optical loss measurement of the plurality of optical fibers 5, and the optical loss is more economical and dense. It is possible to construct a system for measuring
[0139]
Further, in the fifth embodiment, since the 2 × N optical switch 28 is provided, by controlling the 2 × N optical switch 28 and the optical pulse tester 1 remotely and automatically, the optical loss differs from the example of FIG. It is not necessary to attach the optical pulse tester 1, the optical fiber 3, and the optical reflector 4 to the optical fiber 5 for each measurement.
[0140]
【The invention's effect】
As can be seen from the above description, according to the present invention, when measuring the optical loss of an optical fiber line using an optical pulse tester, the optical fiber to be measured is measured. Light After connecting the coupler, the reflection level at both ends of the optical fiber line to be measured, the return loss of the first and second optical reflectors, and ,light The optical loss value is calculated based on the loss value between the ports of the multiplexer / demultiplexer. Accordingly, it is possible to avoid a decrease in measurement accuracy of light loss due to the influence on the backscattered light level at both ends of the optical fiber to be measured due to Fresnel reflection. That is, the optical loss from the near end to the far end of the optical fiber to be measured can be accurately measured.
[0141]
In particular, when an optical multiplexer / demultiplexer is used, the optical loss of the optical fiber to be measured can be measured by one measurement.
[0142]
Further, when the second optical reflector is built in the connector at the far end of the optical fiber to be measured in advance, it is not necessary to manually connect the second optical reflector to the optical fiber to be measured locally at every measurement. .
[0143]
Further, when the second optical reflector is built in the connector at the far end of the optical fiber to be measured in advance, the optical loss is accurately measured without affecting the communication at the time of optical communication of the current optical fiber line. It becomes possible.
[0144]
Furthermore, the function of inserting the test light into the optical fiber to be measured and the function of measuring the reflected light from the first optical reflector can be integrated economically and densely with a single optical coupler. It is possible to construct a system for measuring In this case, by using a 2 × N optical switch, a single first optical reflector can be shared by a plurality of optical fibers to be measured, and a system for measuring optical loss at a high cost and high density is constructed. can do.
[Brief description of the drawings]
FIG. 1 is a diagram showing a measurement system according to a first embodiment of the present invention.
FIG. 2 is a diagram showing an example of a response light waveform in the first embodiment.
FIG. 3 is a diagram showing a measurement system according to a second embodiment of the present invention.
FIG. 4 is a diagram showing an example of a response wave form in the second embodiment.
FIG. 5 is a diagram showing a first embodiment (a connector with a reflector) of a third embodiment of the present invention;
FIG. 6 is a diagram showing a specific configuration example of a connector with a reflector.
FIG. 7 is a diagram showing another specific configuration example of the connector with a reflector.
FIG. 8 is a diagram showing a measurement system of Part 2 of the third embodiment of the present invention.
FIG. 9 is a diagram showing a measurement system of Part 3 of the third embodiment of the present invention.
FIG. 10 is a diagram showing a measurement system of Part 4 of the third embodiment of the present invention.
FIG. 11 is a diagram showing a measurement system of Part 5 of the third embodiment of the present invention.
FIG. 12 is a diagram showing a measurement system according to a fourth embodiment of the present invention.
FIG. 13 is a diagram showing a measurement system according to a fifth embodiment of the present invention.
FIG. 14 is a diagram showing a measurement system of a first conventional example.
FIG. 15 is a diagram showing an example of a response wave form in the first conventional example.
FIG. 16 is a diagram showing a measurement system of a second conventional example.
FIG. 17 is a diagram showing a measurement system of a third conventional example.
FIG. 18 is a diagram showing a measurement system of a fourth conventional example.
FIG. 19 is a diagram showing an example of a response wave form in the fourth conventional example.
[Explanation of symbols]
A, B, C, D Optical input / output port
e Far end
s Near end
1 Optical pulse tester
2 1 × 2 optical switch
3 Optical fiber (another optical fiber or first optical fiber)
4 Light reflector (first light reflector)
5 Optical fiber (measurement target)
6 Light reflector (second light reflector)
6a Light reflector that transmits communication light and reflects test light (second light reflector)
7 Fusion splice points
8 Connector connection points
9 Near-end connector
10 Connector approaching the far end
11 Far end connector
11a Connector with reflector (far-end connector with built-in light reflector 6a)
12 Fresnel reflection from the first reflector
13 Fresnel reflection from the second reflector
14 Optical multiplexer / demultiplexer with three optical input / output ports
15 Communication light
16 test light
17 Connector ferrule
18 Dielectric multilayer filter
19 Fiber grating filter
20, 21 Transmission device
22 Optical coupler
23 Test light blocking filter
24 Optical fiber (second optical fiber)
25 Communication light blocking filter
26 Connector
27 Optical fiber
28 1 × N optical switch
29 heads (1 core)
30 Optical multiplexer / demultiplexer with 4 optical input / output ports
31 2 × N optical switch
32 heads (2 cores)
33 Test light blocking filter
34 Optical fiber
35, 36 Fresnel reflection

Claims (1)

An optical pulse test in which an optical pulse is incident from one end of an optical line, response light comprising backscattered light and Fresnel reflected light generated in the optical line is received, and characteristics of the optical line are measured from the received response light waveform In the optical fiber loss measurement method using a measuring instrument,
A port, B port, C port, D port and four optical input / output ports, light is branched or branched from A port to B port, and from A port to C port, and D port A plurality of optical multiplexers / demultiplexers in which a plurality of optical fibers to be measured are connected to the C port, respectively, from the D port to the B port and from the D port to the C port.
Using 2 × N optical switch,
One side of the optical fiber to be measured is connected to the C port of the optical coupler, and the A port and B port of the plurality of optical couplers are connected in pairs to the N core side of the 2 × N optical switch, One end of the first optical fiber different from the optical fiber to be measured is connected to the two cores of the 2 × N optical switch, and the optical pulse tester is connected to the other end of the first optical fiber. By connecting the first optical reflector to the two cores of the 2 × N optical switch, the 2 × N light can be shared by a plurality of optical fibers to be measured. The optical pulse tester and the first optical reflector are connected in pairs to the two cores of the switch, and are built in the connector at the far end of the optical fiber to be measured at the other end of the optical fiber to be measured. Light that has the property of transmitting communication light and reflecting test light Connecting the second light reflector which comprises using a morphism device, the connect another second optical fiber to the measurement target optical fiber to the D port of the optical splitter,
With the 2 × N optical switch, the optical pulse tester and the first optical reflector can be shared with respect to all the optical optical couplers, and any one optical coupler is selected from the plurality of optical couplers. And
The path of the test light through the light division multiplexer from the 2 × N optical switch test light is branched, one leads to the optical switch again, then, the first optical reflector, the optical division multiplexer, the 2 × N optical switch, the other split by the optical division multiplexer is via the optical fiber, the 2 × N optical switch, respectively, so as to reach the optical pulse tester,
At that time,
The Fresnel reflection level RA (dB) from the first optical reflector and the Fresnel reflection level RB (dB) from the second optical reflector through the arbitrary optical coupler and the 2 × N optical switch. Measure and
The return loss of the first optical reflector is RLossA (dB), the return loss of the second optical reflector is RLossB (dB), and the loss between the A port and the B port of any one optical multiplexer / demultiplexer is Loss between the A port and the C port of the arbitrary optical coupler / branch is CL LossAC (dB), and the 2 × N light between the arbitrary optical coupler / branch and the first optical reflector. When the switch connection loss is WLoss (dB)
The optical loss FLoss from the near end to the far end of the optical fiber to be measured is
FLoss = (RLossA + (RA / 2) + CLossAB + WLoss)-(RLossB + (RB / 2) + CLossAC + WLoss)
An optical fiber loss measuring method characterized in that it is obtained by a single measurement from the equation (1).

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