JP2013040816A - Optical pulse tester - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance convenience of measurement work before and after construction in interference relocating work in an optical pulse tester.SOLUTION: An optical pulse tester includes: a measurement processing part in which an optical pulse is made incident on an optical fiber to be measured and light returning to an incident end is measured in a time domain; an operation reception part; a display part; and a measurement control part in which, when a first measurement start instruction is received via the operation reception part, the measurement processing part is made to start measurement and the first measurement start instruction is recorded as first measurement data after termination of the measurement, and when a second measurement start instruction is received via the operation reception part, the measurement processing part is made to start the measurement, and the recorded first measurement data and second measurement data during measurement are made to be displayed in the display part.

Description

  The present invention relates to an optical pulse tester, and more particularly to an optical pulse tester that enhances the convenience of measurement work before and after construction in trouble relocation work.

  In an optical communication system that performs data communication using an optical signal, an optical fiber is used as a medium for transmitting the optical signal. Optical fiber length, connection loss, reflection, etc. need to be evaluated for laying optical fiber, relocating trouble, maintenance, etc. Optical pulse tester (OTDR: Optical Time Domain Reflectometer) ) Is used. The optical pulse tester is a device that performs display / analysis and the like by measuring an optical pulse incident on an optical fiber to be measured and measuring light returning to the incident end in a time domain.

JP 2008-249471 A

  In obstacle relocation work that changes the route of the installed optical fiber, an operator (user) measures the optical fiber using an optical pulse tester before and after the construction. Then, the measurement data before and after the construction are compared, and it is confirmed that the same characteristics as before the construction can be obtained after the construction, and the construction is completed.

  Since the obstacle relocation work changes the route of existing cables that are in use, it is necessary to avoid long-term work that prevents data communication. For this reason, it is desirable to improve the convenience of measurement work so that optical fiber measurement before and after construction using an optical pulse tester can be performed as quickly as possible.

  Therefore, an object of the present invention is to increase the convenience of measurement work before and after construction in trouble relocation work in an optical pulse tester.

  In order to solve the above problems, the optical pulse tester of the present invention includes a measurement processing unit that measures the light that enters the optical fiber to be measured and returns to the incident end in the time domain, an operation receiving unit, When the first measurement start instruction is received via the display unit and the operation receiving unit, the measurement processing unit starts measurement, and after the measurement is completed, the first measurement data is recorded, and then the second measurement unit is set via the operation receiving unit. A measurement control unit that, upon receiving a measurement start instruction, causes the measurement processing unit to start measurement and displays the recorded first measurement data and second measurement data being measured on the display unit; And

  Here, the operation reception unit includes an operation element for switching between the first measurement and the second measurement and an operation element for a measurement start instruction. When the measurement start instruction is received when the first measurement is switched, the first measurement start instruction If a measurement start instruction is accepted at the time of switching the second measurement, it can be regarded as the second measurement start instruction.

  The first measurement may be a measurement before construction, and the second measurement may be a measurement after construction. The recording of the first measurement data can be performed without accepting a storage instruction via the operation accepting unit.

  ADVANTAGE OF THE INVENTION According to this invention, the convenience of the measurement work before and behind construction in trouble transfer work can be improved in an optical pulse tester.

It is a block diagram which shows the structure of the optical pulse tester which concerns on this embodiment. It is a figure which shows the example of an external appearance of an operation reception part and a display part. It is a figure explaining basic trouble transfer work. It is a flowchart explaining the basic operation | movement of the optical pulse tester in the case of using it for the trouble transfer construction of an optical fiber. It is a figure which shows the example of a screen which displayed the measurement waveform before construction, and the newest waveform of the measurement data after construction on the same screen. It is a figure explaining the obstacle transfer construction of a splitter lower part. It is a flowchart explaining operation | movement of the optical pulse tester in the case of using it for the trouble transfer work of the splitter lower part. It is a figure which shows the example of a screen which displayed the measurement waveform before construction in the trouble transfer work of the lower part of a splitter, and the newest waveform of the measurement data after construction on the same screen. It is a figure which shows the example of a screen which accumulated and displayed the difference waveform D on the waveform before construction, and the waveform after construction. It is a figure explaining the obstacle transfer construction of a multi-core optical fiber. It is a flowchart explaining operation | movement of the optical pulse tester in the case of using for the pass / fail determination of the measurement waveform using a loss value. It is a figure explaining a pass / fail judgment marker. It is a figure which shows the example of a screen which shows a pass / fail determination result. It is a figure which shows the example of a screen which showed the pass / fail determination result in the list of core wires.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of an optical pulse tester according to the present embodiment. As shown in this figure, the optical pulse tester 100 is a device that performs a display / analysis etc. by measuring a light pulse incident on an optical fiber 200 to be measured and returning to the incident end in the time domain. A measurement processing unit 110, a connector 115, a measurement control unit 120, an operation receiving unit 130, a display unit 140, and a storage unit 150. In this embodiment, the optical fiber 200 is assumed to be a multi-core optical fiber including a large number of core wires, and the measurement is performed by connecting the core wire to be measured to the connector 115. Of course, the optical fiber 200 to be tested may be a single core.

  The measurement processing unit 110 includes a light emitting unit 111, an optical coupler 112, a light receiving unit 113, and a signal processing unit 114. The light emitting unit 111 can be configured by a laser diode or the like, and emits light at a predetermined interval by the pulse signal generated by the signal processing unit 114 to generate an optical pulse.

  The optical coupler 112 makes an optical pulse generated by light emission from the light emitting unit 111 incident on the optical fiber 200 to be measured via the connector 115, and makes return light from the optical fiber 200 incident via the connector 115. Lead to 113. The return light from the optical fiber 200 includes backscattered light due to Rayleigh scattering inside the optical fiber 200 and Fresnel reflected light generated at the connection point.

  The light receiving unit 113 can be configured by a photoelectric element or the like, and converts the return light into an electrical signal. The signal processing unit 114 generates a pulse to be supplied to the light emitting unit 111 and samples the electrical signal converted by the light receiving unit 113 at a timing synchronized with the pulse. Since the return light from the optical fiber 200 is weak, sampling by the signal processing unit 114 is repeatedly performed for a large number of optical pulses and averaged by the measurement control unit 120.

  The measurement control unit 120 provides a user interface via the operation receiving unit 130 and the display unit 140 and controls the measurement operation and the analysis operation in the optical pulse tester 100. Specific operation of the measurement control unit 120 will be described later.

  The operation receiving unit 130 can be configured with buttons, switches, dial knobs, touch panels, and the like, and receives various operations related to the optical pulse test from the user. The display unit 140 can be configured by a liquid crystal display panel or the like, and displays a measurement waveform, an operation menu, and the like under the control of the measurement control unit 120. The storage unit 150 can be configured by a hard disk device, a semiconductor storage device, or the like, and records measurement data and the like under the control of the measurement control unit 120.

  FIG. 2 is a diagram illustrating an external appearance example of the operation receiving unit 130 and the display unit 140. In the present embodiment, the operation receiving unit 130 includes a power switch 131, a rotary knob 132, a scale key 133, a direction / enter key 134, a setup (SETUP) key 135, a real-time measurement (REAL TIME) key 136, and an averaged measurement (AVE). A key 137 and a function key 138 are provided.

  In the present embodiment, the operation content of the function key 138 is displayed at a corresponding position on the display unit 140. However, the display unit 140 may be configured with a touch panel so that instructions can be given on the screen.

On the screen of the display unit 140, a list of identifiers for identifying the core wires corresponding to the multi-fiber optical fiber 200 is displayed. The user can associate the measurement result with the core wire by selecting the identifier corresponding to the core wire to be measured. In this list, a check mark indicating that the measurement is completed is displayed on the identifier of the core wire.
<First operation example>

  The operation of the optical pulse tester 100 having the above configuration will be described. First, a basic operation when the optical pulse tester 100 is used for trouble relocation work of the optical fiber 200 will be described. Here, as shown in FIG. 3, it is necessary to change the route of the installed optical fiber 200a, the optical fiber 200a is cut at the points A and B, and the optical fiber 200b laid on a new route is fused. Construction to be connected shall be performed. 3A shows an optical fiber path before construction, and FIG. 3B shows an optical fiber path after construction. In this case, it is necessary to confirm that the route after construction can obtain the same characteristics as the route before construction. For this purpose, an optical pulse tester 100 is used to measure characteristics before and after construction.

  FIG. 4 is a flow chart for explaining the basic operation of the optical pulse tester when used for the work for relocating an optical fiber trouble. First, in order to perform pre-construction measurement, a pre-construction measurement instruction is received from the user (S101). The pre-construction measurement instruction can be received by, for example, “F1” corresponding to the display “pre-construction” of the function keys 138 shown in FIG. As described above, in the optical pulse tester 100 of the present embodiment, it is possible to explicitly accept the measurement before the construction, and the user can operate intuitively and easily.

  Then, a measurement start instruction is received from the user (S102). Note that settings of measurement conditions such as range and number of averaging may be received before the start of measurement. The measurement start instruction can be received by, for example, the real-time measurement (REAL TIME) key 136 and the averaged measurement (AVE) key 137 shown in FIG. That is, the user can select either real-time measurement in which the average value of measurement results is sequentially updated, or averaged measurement in which measurement is performed for the set number of averaging times and the measurement result is output.

  When receiving the measurement start instruction, the optical pulse tester 100 performs measurement, and repeats the measurement data averaging process (S103) until the measurement is completed (S104). Here, the end of measurement is, for example, in the case of real-time measurement, when the real-time measurement (REAL TIME) key 136 is pressed again, in the case of averaged measurement, when the set number of averaging is repeated, etc. Can do.

  When the measurement before construction is completed (S104: Yes), the measurement data file before construction is stored in the storage unit 150 (S105). At this time, information for identifying the core wire to be measured is added to the file. An identifier may be included in the file name. The file is automatically saved with the end of measurement as a trigger. For this reason, the user does not need to separately perform an operation for saving a file, and the operation is simplified.

  Then, the person in charge of the construction cuts the core wire at the switching position of the optical fiber 200a, and performs the core wire switching work for fusion-connecting the core wires of the optical fiber 200b laid on the new route. You may make it confirm a cutting | disconnection using the optical pulse tester 100 after a core wire cutting | disconnection.

  When the core switching work is completed, a post-construction measurement instruction is received from the user in order to perform post-construction measurement (S106). The pre-construction measurement instruction can be received by, for example, “F2” corresponding to the display “after construction” in the function keys 138 shown in FIG. As described above, in the optical pulse tester 100 of the present embodiment, it is possible to explicitly accept the measurement after the construction, and the user can operate intuitively and easily.

  Then, a measurement start instruction is received from the user (S107). The measurement start instruction can be received by the same method as the measurement start instruction before construction. The measurement conditions, measurement method, etc. at this time are the same as those before the construction.

  In the measurement after the construction, when receiving the measurement start instruction, the optical pulse tester 100 reads the measurement data file before the construction and displays the waveform on the display unit 140 for reference (S108). For this reason, the user can confirm the measurement data before construction at the time of measurement after construction.

  Then, the measurement is executed, the measurement data is averaged (S109), and the latest waveform of the measurement data after the construction is displayed on the same screen as the measurement waveform before the construction (S110).

  FIG. 5 shows a screen example in which the measurement waveform before construction and the latest waveform of the measurement data after construction are displayed on the same screen. As described above, in the optical pulse tester 100 of the present embodiment, the measurement waveform after the construction can be compared with the measurement waveform before the construction simultaneously with the execution of the measurement after the construction. Can be easily confirmed. For this reason, it is not necessary to call and compare the measurement data file before the construction after the completion of the measurement after the construction, and the working time can be greatly shortened.

  The averaging of the measurement data after construction (S109) and the display of the latest waveform of the measurement data after construction (S110) are repeated until the measurement is completed (S111). If the construction result can be confirmed with a certain number of averaging times, the user can stop the measurement. Thereby, construction time can be further shortened.

  When the measurement after the construction is finished (S111: Yes), the measurement data file after the construction is stored in the storage unit 150 (S112). At this time, information for identifying the core wire to be measured is added. The file is automatically saved with the end of measurement as a trigger. After that, by automatically returning to the main screen displaying the list of optical fiber core line identifiers shown in FIG. 2, it is possible to quickly move to the next core line measurement. At this time, a check mark indicating that measurement has been completed is superimposed on the identifier of the measured core wire. Further, when the identifier of the measured core wire is focused, for example, measurement waveforms before and after construction are displayed in the lower right area.

As described above, the optical pulse tester 100 according to the present embodiment can perform processing specialized for the work flow of trouble relocation work, and automatically performs screen information and operation feeling corresponding to actual work. Can be provided. For this reason, the complexity of the operator's procedure can be eliminated.
<Second operation example>

  Next, an operation in the case where the optical pulse tester 100 is used for the obstacle relocation work under the splitter will be described. Here, as shown in FIG. 6A, when the lower portion of the splitter 300 is branched into three points of A connection point, B connection point, and C connection point, as shown in FIG. Construction that changes the route to the connection point shall be performed.

  At this time, as shown on the right side of FIGS. 6A and 6B, the position of the Fresnel reflection from the B connection point and the C connection point does not change before and after the construction, and the Fresnel reflection from the A connection point. It is necessary to confirm that only the position of changes. For this reason, the optical pulse tester 100 is used to measure the characteristics before and after construction.

  FIG. 7 is a flowchart for explaining the operation of the optical pulse tester 100 when it is used for the obstacle relocation work under the splitter. The basic operation is the same as that of the first operation example, and the description of the same operation as that of the first operation example will be simplified.

  First, in order to perform measurement before construction, a pre-construction measurement instruction is received from the user (S201). Then, a measurement start instruction is received from the user (S202).

  When receiving the measurement start instruction, the optical pulse tester 100 performs the measurement and repeats the measurement data averaging process (S203) until the measurement is completed (S204). When the measurement before construction is completed (S204: Yes), the measurement data file before construction is stored in the storage unit 150 (S205).

  Then, the person in charge of the construction cuts the core wire at the route switching point to the A connection point below the splitter 300, and performs the core wire switching work for fusion-connecting the core wires laid on the new route. You may make it confirm a cutting | disconnection using the optical pulse tester 100 after a core wire cutting | disconnection.

  When the core switching work is completed, a post-construction measurement instruction is received from the user in order to perform post-construction measurement (S206). Next, a measurement start instruction is received from the user (S207).

  In the measurement after the construction, when receiving the measurement start instruction, the optical pulse tester 100 reads the measurement data file before the construction and displays the waveform on the display unit 140 for reference (S208). Then, the measurement is executed, the measurement data is averaged (S209), and the latest waveform of the measurement data after the construction is displayed on the same screen as the measurement waveform before the construction (S210).

  FIG. 8 shows a screen example in which the measurement waveform before construction and the latest waveform of the measurement data after construction are displayed on the same screen. On this screen, the user can instruct the display of the differential waveform between the pre- and post-construction waveforms. The display of the differential waveform can be received by, for example, “F3” corresponding to the display “differential waveform OFF ON” of the function keys 138.

  When there is an instruction to display a differential waveform (S211: Yes), the optical pulse tester 100 superimposes the differential waveform between the waveform before construction and the waveform after construction on the waveform before construction and the waveform after construction. Are displayed (S212). At this time, the horizontal axes of the three waveforms are aligned.

  FIG. 9 shows a screen example in which the differential waveform D is displayed superimposed on the waveform before construction and the waveform after construction. In the differential waveform, since the change in waveform before and after the construction is extracted, it is possible to easily confirm the location where the Fresnel reflection is moved due to the obstacle relocation work under the splitter 300. In the example of this figure, D1 shows the Fresnel reflection position before construction of the A connection point, and D2 shows the Fresnel reflection position after construction of the A connection point. The other parts do not change before and after construction, so there is no difference.

  The averaging of the measurement data after the construction (S109), the display of the latest waveform of the measurement data after the construction (S110), and the differential waveform display (S212) when the display is instructed are repeated until the measurement is completed (S213).

  When the measurement after the construction is completed (S213: Yes), the measurement data file after the construction is stored in the storage unit 150 (S214). At this time, information for identifying the core wire to be measured is added. The file is automatically saved with the end of measurement as a trigger.

As described above, the optical pulse tester 100 according to the present embodiment can display the difference waveform between the pre-construction waveform and the post-construction waveform at the time of measurement after the construction. Can be performed easily and quickly.
<Third operation example>

  Next, an operation when the optical pulse tester 100 is used for pass / fail determination of a measurement waveform using a loss value will be described. Here, each core wire of the multi-fiber optical fiber 200c shown in FIG. 10 (a) is cut, and an optical fiber newly laid at the connection point a and the connection point b as shown in FIG. 10 (b). It is assumed that construction for connecting the 200d core wires is performed.

  In this case, it is necessary to confirm that the loss value at the connection point is within a certain range for each core wire. For this reason, the optical pulse tester 100 is used, and as shown in FIG. 10 (c), the loss after the construction is measured at the connection portion of each core wire. Since each core wire of the optical fiber 200c is cut and connected at the same location, a loss occurs at the same location for each core wire.

  FIG. 11 is a flowchart for explaining the operation of the optical pulse tester 100 when used for pass / fail determination of a measurement waveform using a loss value. Here, the description will be given focusing on measurement after construction.

  First, the core wire to be measured is specified (S301). The core wire to be measured can be specified by selecting the identifier of the core wire to be measured on the screen shown in FIG. This operation can be performed using, for example, the direction / enter key 134.

  When an instruction to start measurement is received from the user (S302), the measurement waveform before construction is displayed for reference (S303). Then, the measurement after the construction is executed, the averaging process is performed (S304), and the measurement waveform after the construction is displayed (S305).

  In the present embodiment, a pass / fail judgment marker can be used so that the loss in the troubled transfer work of a multi-fiber optical fiber can be easily confirmed. The pass / fail determination marker is a marker applied to all the cores, and can be set for the marker position, the loss evaluation method, and the pass / fail determination threshold. By using a pass / fail determination marker, a common marker can be set for each core wire all at once, so that it is not necessary to set a marker for each core wire individually in order to confirm the loss of each core wire. Here, the conventional marker is a tool for calculating a loss value, an attenuation amount, and the like at a position where an event such as a connection loss occurs.

  When an instruction for setting the pass / fail determination marker is received from the user (S306: Yes), the optical pulse tester 100 proceeds to a process for receiving the setting of the pass / fail determination marker (S307). An instruction to set the pass / fail judgment marker can be received by, for example, “F4” corresponding to the display of “pass / fail judgment marker” in the function keys 138 shown in FIG.

  For example, as shown in FIG. 12, the pass / fail judgment marker can be set on a screen that displays waveforms before and after construction. The user can select a two-point method for designating two points on the waveform, a four-point method for designating four points, or the like as loss evaluation. Of course, other methods may be selected.

  When the user selects the two-point method, for example, by operating the rotary knob 132 and moving the cursor displayed on the screen, two points for confirming the loss are set. Two points are event locations where loss occurs on the screen. When the positions of these two points are set for a certain core, they are commonly applied to all the cores. In trouble-removing work for multi-core optical fibers, the locations where connection loss occurs are the same, so if a loss position is set for a certain core, that position can also be applied to other cores. If the position of the construction site can be identified, the pass / fail judgment marker may be set before the target core wire is identified or before the measurement after the construction.

  Further, the user can set a threshold value used for the pass / fail determination of the loss value. That is, if the loss value at the location set by the pass / fail determination marker is within the threshold value, the core wire is determined to be acceptable. The threshold value set by the pass / fail judgment marker is also commonly applied to all the core wires.

  In the measurement after the construction, if the pass / fail determination marker has been set (S308: Yes), the pass / fail determination is performed by comparing the loss value obtained by the pass / fail determination marker with the set threshold value (S309). The acceptance / rejection determination is sequentially performed during the measurement execution after the construction, and the determination result is displayed (S310). FIG. 13 shows an example of a screen showing the pass / fail judgment result. In the example of this figure, the position of the pass / fail judgment marker is indicated by (1) and (2), and the result of the pass / fail judgment is displayed on the upper right. The result of the pass / fail judgment is updated every averaging. When the pass / fail determination result changes, the user may be alerted by sounding a buzzer or the like.

  Since the pass / fail determination of the present embodiment is performed based on the loss value and the threshold value rather than the visual observation of the user, stable determination without variations and determination errors can be performed.

  The above processing is repeated until the measurement is completed (S311). When the user confirms the pass with a certain number of averaging times, the user can finish the post-construction measurement for the core and perform measurement for another core. Thereby, measurement time can be shortened.

  When the measurement is completed for a certain core (S311: Yes), the measurement data is saved as a file and the determination result is recorded (S312). As shown in FIG. 14, the determination result is displayed so as to be superimposed on the list of core lines. In the example shown in the figure, for a core wire that has passed, a check mark indicating that the measurement has been completed is overlaid on the check mark, and for a core wire that has failed, a check mark indicating that the measurement has been completed is “! "Is superimposed and displayed. Thereby, the user can confirm the measurement result of a core wire easily.

  If there is another core wire to be measured (S313: Yes), the process returns to the process of specifying the target core wire (S301), and the subsequent processing is repeated. If there is no other core wire to be measured (S313: No), this process ends.

DESCRIPTION OF SYMBOLS 100 ... Optical pulse tester, 110 ... Measurement processing part, 111 ... Light emission part, 112 ... Optical coupler, 113 ... Light receiving part, 114 ... Signal processing part, 115 ... Connector, 120 ... Measurement control part, 130 ... Operation reception part, 131 ... Power switch, 132 ... Rotary knob, 133 ... Scale key, 134 ... Direction / Enter key, 135 ... SETUP key, 136 ... Real time measurement key, 137 ... Average measurement key, 138 ... Function key, 140 ... Display unit, 150 ... Storage unit, 200 ... Optical fiber, 300 ... Splitter

Claims (4)

A measurement processing unit that measures the light that enters the optical fiber to be measured and returns to the incident end in the time domain;
An operation reception unit;
A display unit;
When a first measurement start instruction is received via the operation reception unit, the measurement processing unit starts measurement, and records the first measurement data after the measurement is completed.
When a second measurement start instruction is received via the operation receiving unit, measurement control is performed so that the measurement processing unit starts measurement, and the display unit displays the recorded first measurement data and second measurement data being measured. And
An optical pulse tester comprising: The operation reception unit includes an operator for switching between the first measurement and the second measurement and an operator for a measurement start instruction,
2. The apparatus according to claim 1, wherein when a measurement start instruction is received at the time of switching the first measurement, the first measurement start instruction is considered, and when a measurement start instruction is received at the time of the second measurement change, the second measurement start instruction is considered. Optical pulse tester.   3. The optical pulse tester according to claim 1, wherein the first measurement is a measurement before construction, and the second measurement is a measurement after construction. 4.   The optical pulse tester according to any one of claims 1 to 3, wherein the recording of the first measurement data is performed without accepting a storage instruction via the operation accepting unit.