JP4016693B2 - Optical fiber evaluation method and evaluation apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical fiber evaluation method and an evaluation apparatus for evaluating an optical fiber using an OTDR waveform measured by an OTDR apparatus.
[0002]
[Prior art]
OTDR waveform (Optical Time-Domain Reflectometer) due to backscattering of pulsed light is measured as a method for evaluating the optical fiber by judging the presence / absence of the optical fiber and the location and range of the abnormality. Is used to evaluate optical fiber anomalies. Such an optical fiber evaluation method is described in, for example, Japanese Patent Laid-Open Nos. 10-332530 and 9-269279.
[0003]
In an optical fiber evaluation method using an OTDR waveform, an optical fiber to be evaluated is connected to an OTDR apparatus, and pulsed light is incident on the optical fiber. Then, the return light power to the OTDR device due to backscattering generated at each position of the optical fiber is detected, and the optical fiber is evaluated from the waveform (OTDR waveform) with respect to the time. The return light to the OTDR device corresponds to the optical loss at each position of the optical fiber, and therefore the abnormality of the optical fiber can be evaluated from the abnormality of the waveform.
[0004]
[Problems to be solved by the invention]
In the optical fiber evaluation method described above, it is important to reliably determine an abnormality in the optical fiber from the measured OTDR waveform. On the other hand, Japanese Patent Laid-Open No. 10-332530 describes that an average loss value in a measured waveform or a standard value instead thereof is used to print a difference from the standard value of the loss value at each time point. Has been. Here, in this method, an abnormality in the optical fiber is determined by the evaluator's visual observation based on the difference data from the printed standard value. For this reason, the criterion for determining abnormality is not clear, and abnormality of the optical fiber cannot be reliably evaluated.
[0005]
Japanese Patent Laid-Open No. 9-269279 discloses an approximate straight line with respect to an OTDR waveform by the method of least squares, and the slope of the waveform at the point where the smoothed waveform and the approximate straight line intersect, In addition, it is described that the abnormality in the optical fiber is determined from the length in which the inclination is in the same direction. However, in this method, there is a problem that it is impossible to determine an abnormality of the optical fiber unless the waveform and the approximate line intersect.
[0006]
The present invention has been made to solve the above problems, and an object of the present invention is to provide an optical fiber evaluation method and an evaluation apparatus capable of reliably evaluating an optical fiber abnormality from an OTDR waveform. To do.
[0007]
[Means for Solving the Problems]
In order to achieve such an object, the optical fiber evaluation method according to the present invention detects the return light power from the optical fiber by injecting pulsed light into the evaluation target optical fiber, and generates a waveform of the return light power with respect to time. An evaluation method for evaluating an optical fiber by measuring: (1) an approximate straight line calculating step for obtaining an approximate straight line for a portion of the waveform to be evaluated; and (2) a deviation from a difference between the portion to be evaluated of the waveform and the approximate straight line. A deviation waveform calculation step for obtaining a waveform; and (3) for a deviation waveform, a first reference value at which the deviation is maximum or maximum, and a second reference value at which the deviation is minimum or minimum are determined, and the first reference value and the second reference value A difference value calculating step for calculating the difference value of the optical fiber, and (4) a difference value determining step for determining whether or not the optical fiber is abnormal depending on whether the difference value satisfies a predetermined condition. (5) a dividing point determining step for determining a dividing point capable of reducing the abnormality by dividing the optical fiber when an abnormality of the optical fiber is determined; It is characterized by providing.
[0008]
Further, the optical fiber evaluation apparatus according to the present invention evaluates an optical fiber by detecting pulsed light incident on the optical fiber to be evaluated, detecting the return light power from the optical fiber, and measuring the waveform of the return light power with respect to time. And (1) an approximation line calculating means for obtaining an approximate line for a portion of the waveform to be evaluated, and (2) a deviation waveform calculating means for obtaining a deviation waveform from a difference between the portion to be evaluated of the waveform and the approximate line. (3) A difference value for calculating a difference value between the first reference value and the second reference value by obtaining a first reference value having a maximum or maximum deviation and a second reference value having a minimum or minimum regarding the deviation waveform. (4) difference value determination means for determining an optical fiber abnormality depending on whether the difference value satisfies a predetermined condition; (5) a division point determination means for determining a division point capable of reducing the abnormality by dividing the optical fiber when an abnormality of the optical fiber is determined; It is characterized by providing.
[0009]
In the above-described optical fiber evaluation method and evaluation apparatus, the difference value of the deviation representing the deviation from the waveform straight line is calculated from the deviation waveform between the OTDR waveform and the approximate straight line, and whether or not the difference value satisfies a predetermined condition. Is used to evaluate optical fiber abnormalities. Thereby, even if it is a normal case from the viewpoint of the loss in the optical fiber, it is possible to reliably evaluate an optical fiber abnormality such as a deviation abnormality in a wide range. In particular, by using the difference value calculated from the maximum value or maximum value of the deviation and the minimum value or minimum value for determining an abnormality, it is possible to correctly evaluate the magnitude of deviation from the straight line of the waveform. .
[0010]
Here, for the derivation of the first reference value and the second reference value from the deviation waveform, in the difference value calculation step (difference value calculation means), the deviation waveform is divided into a plurality of sections with respect to time in advance, It is preferable to average the difference for each section. Thereby, it is possible to reduce the influence of minute fluctuations such as noise in the deviation waveform, and to reliably determine the abnormality of the optical fiber.
[0011]
Further, the optical fiber evaluation method (evaluation apparatus) includes a division point determination step (a division point) for determining a division point that can reduce an abnormality by dividing the optical fiber when an optical fiber abnormality is determined. Determining means).
[0012]
As described above, by determining a suitable dividing point of the optical fiber for an optical fiber abnormality such as a deviation abnormality in a wide range determined by the above-described method, the optical fiber in which the abnormality is determined can be improved. It becomes possible to divide and use into two or more optical fibers having characteristics.
[0013]
In this case, the evaluation method includes a waveform division step of dividing the waveform by the division points, and for each of the divided waveforms, an approximate straight line calculation step, a deviation waveform calculation step, a difference value calculation step, and a difference value determination step Are preferably performed. Thereby, when an optical fiber is divided at the determined dividing point, it can be determined in advance whether each of the two or more optical fibers obtained by the division is an optical fiber having good characteristics.
[0014]
Further, the present invention is characterized by comprising an abnormality determination step of calculating an inclination of the waveform at each time point and determining an abnormality of the optical fiber depending on whether or not the calculated inclination value is within a predetermined range. In this way, in addition to the evaluation of optical fiber abnormality using the difference value of the deviation in the deviation waveform, the evaluation method using the slope at each time point of the waveform is used in combination, so that the optical fiber abnormality is more reliably performed. Can be evaluated.
[0015]
In addition, the waveform is divided into a plurality of sections with a predetermined section width, and a section approximation straight line for the waveform in each section is obtained for each of the plurality of sections, and the slope value of the section approximation straight line is within a predetermined range. An abnormality determination step for determining an abnormality of the optical fiber according to whether or not there is an abnormality is provided. In this way, in addition to the evaluation of the optical fiber abnormality using the difference value of the deviation in the deviation waveform, the evaluation method using the slope of the approximate straight line in each section of the waveform is used in combination, so that the light is more reliably transmitted. It becomes possible to evaluate the abnormality of the fiber.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of an optical fiber evaluation method and an evaluation apparatus according to the present invention will be described in detail with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted. Further, the dimensional ratios in the drawings do not necessarily match those described.
[0017]
Here, the slope of the OTDR waveform corresponds to a local loss value at each position of the optical fiber or a loss value in each divided section. Therefore, in the following, regarding the sign of the slope of the waveform and the approximate line, the direction in which the slope increases and the loss value in the optical fiber increases is the positive direction, and the slope decreases and the loss value in the optical fiber decreases. This direction will be described as a negative direction.
[0018]
FIG. 1 is a block diagram showing a configuration of an embodiment of an optical fiber evaluation apparatus according to the present invention. The optical fiber evaluation apparatus 1 includes a waveform measurement unit 2 that measures an OTDR waveform and a waveform evaluation unit 3 that evaluates the measured waveform. The waveform evaluation unit 3 includes a calculation unit 4 that calculates a data value necessary for the evaluation of the optical fiber, and a determination unit 5 that determines an abnormality of the optical fiber from the calculated data value. Hereinafter, the configuration of the optical fiber evaluation apparatus 1 will be described together with the operation and the optical fiber evaluation method.
[0019]
First, the waveform measurement unit 2 corresponding to the OTDR measurement device will be described. The waveform measurement unit 2 includes a pulse light transmission unit 21, an optical coupler 22, and a return light reception unit 23. The pulsed light transmission unit 21 is made of, for example, a semiconductor laser, and generates and outputs pulsed light having a predetermined wavelength and a predetermined time width used for measurement of the OTDR waveform. The pulsed light transmission unit 21 is optically connected to an optical fiber F that is an object to be evaluated by the optical fiber evaluation apparatus 1 via an optical coupler 22.
[0020]
In addition to the pulsed light transmitter 21, a return light receiver 23 is optically connected to the optical fiber F via an optical coupler 22. The return light receiving unit 23 includes, for example, a semiconductor light receiving element, detects light of a predetermined wavelength input from the optical fiber F, and outputs a detection signal.
[0021]
In such a configuration, when pulse light for optical fiber evaluation is transmitted from the pulse light transmission unit 21 to the optical fiber F via the optical coupler 22, waveform measurement is performed by backscattering at each position of the optical fiber F. Return light to the section 2 is generated. This return light is received and detected by the return light receiver 23 via the optical coupler 22. Thereby, the return light and its power are detected at each time point after the pulse light is transmitted.
[0022]
The detection signal of the return light power output from the return light receiving unit 23 is input to the signal processing unit 24 configured by circuit elements necessary for signal processing such as an A / D converter. The signal processing unit 24 performs signal processing of the detection signal from the return light receiving unit 23 in synchronization with the transmission time of the pulsed light by the pulsed light transmitting unit 21.
[0023]
Specifically, the signal processing unit 24 including an A / D converter or the like performs a number of samplings at a constant cycle from a sampling start time at a fixed time with respect to the pulsed light transmission time by the pulsed light transmission unit 21. At the time, the measured return light power is sampled. This sampling data is the original data of the OTDR waveform that is a waveform with respect to the time of the return light.
[0024]
Here, the time difference between the transmission time of the pulsed light at the pulsed light transmission unit 21 and the sampling time that is the reception time of the return light at the return light receiving unit 23 and the signal processing unit 24 is transmitted to the optical fiber F. The delay time until the light component of the pulsed light is backscattered and returned. That is, this time difference corresponds to the position in the optical fiber F where the measured return light is backscattered. Therefore, by measuring the OTDR waveform with respect to the time of the return light and evaluating the presence / absence of the abnormality in the waveform and the delay time at which the abnormality occurred, the presence / absence of the abnormality in the evaluation target optical fiber F and the position where the abnormality has occurred are determined. Can be evaluated.
[0025]
The operation of each unit in the waveform measuring unit 2 is controlled by the measurement control unit 20. The measurement control unit 20 instructs the pulsed light transmission unit 21 on the transmission time of the pulsed light. Further, the measurement control unit 20 refers to the transmission time of the pulsed light and instructs the signal processing unit 24 the sampling time of the detection signal from the return light receiving unit 23 which is the reception time of the return light. Each data such as the sampling data of the return light power sampled by the signal processing unit 24 is collected by the measurement control unit 20.
[0026]
Next, the waveform evaluation unit 3 corresponding to the OTDR evaluation apparatus will be described. The waveform evaluation unit 3 includes a calculation unit 4 and a determination unit 5.
[0027]
The calculation unit 4 includes a waveform generation unit 40, an approximate straight line calculation unit 41, a deviation waveform calculation unit 42, a difference value calculation unit 43, and a waveform division unit 44. The waveform generation unit 40 receives necessary data such as return optical power sampling data collected by the measurement control unit 20 of the waveform measurement unit 2, and based on the data, generates an OTDR waveform with respect to the time of the return optical power. Generate. The delay time in the waveform with respect to this time corresponds to the position in the optical fiber F as described above.
[0028]
When there is a large statistical fluctuation in the sampling data of the return light power acquired by the waveform measuring unit 2, the waveform generating unit 40 performs a waveform smoothing process using a moving average or the like. Thus, a plurality of data points of the waveform are generated.
[0029]
The approximate line calculation unit 41 obtains an approximate line for the entire waveform of the OTDR waveform generated by the waveform generation unit 40 (approximate line calculation step). This approximate straight line is obtained, for example, by applying the method of least squares to a plurality of data points of the waveform. Further, the deviation waveform calculation unit 42 obtains a deviation waveform from the waveform generated by the waveform generation unit 40 and the approximate straight line calculated by the approximate straight line calculation unit 41 based on the difference between the waveform and the approximate straight line (deviation waveform calculation step). ).
[0030]
Further, the difference value calculation unit 43 calculates a difference value of deviation representing the magnitude of deviation from the straight line of the waveform for the calculated deviation waveform (difference value calculation step). The difference value in the deviation waveform is used for evaluation of the abnormality of the optical fiber by the determination unit 5. Specifically, the difference value calculation unit 43 obtains a first reference value at which the deviation is maximum or maximum and a second reference value at which the deviation is minimum or minimum for the deviation waveform calculated by the deviation waveform calculation unit 42. . Then, a difference value of the deviation is calculated from the difference between the first reference value and the second reference value.
[0031]
The determination unit 5 includes a difference value determination unit 51, an abnormality determination unit 50, and a dividing point determination unit 52.
[0032]
In the difference value determination unit 51, an allowable condition is set in advance for the difference value in the deviation waveform of the OTDR waveform calculated by the difference value calculation unit 43. The difference value determination unit 51 determines whether or not the difference value in the calculated deviation waveform satisfies a predetermined condition, and determines whether or not the optical fiber F is abnormal based on the result (difference value determination step). As an allowable condition for the difference value of the deviation, for example, an allowable deviation range is set as an allowable numerical range. Moreover, the abnormality determination part 50 determines the presence or absence of abnormality in the optical fiber F which is an evaluation object, the position of abnormality, etc. based on the determination result etc. in the difference value determination part 51 (abnormality determination step).
[0033]
In addition, when the difference value determination unit 51 and the abnormality determination unit 50 determine that the optical fiber F is abnormal, the division point determination unit 52 is abnormal by dividing the optical fiber F into two or more optical fibers. The dividing point that can be an optical fiber with reduced is determined (dividing point determination step). When the division point for the optical fiber F is determined, the division point determination unit 52 instructs the waveform division unit 44 of the calculation unit 4 to divide the waveform. The waveform dividing unit 44 divides the OTDR waveform into two or more waveforms by the dividing points corresponding to the dividing points in the optical fiber F determined by the dividing point determining unit 52 (waveform dividing step). Then, for each of the divided waveforms, the approximate line calculation unit 41 calculates the approximate line, the deviation waveform calculation unit 42 calculates the deviation waveform, the difference value calculation unit 43 calculates the difference value of the deviation, and the difference The determination of the abnormality of the optical fiber by the difference value in the value determination unit 51 is repeatedly performed.
[0034]
The effects of the optical fiber evaluation apparatus and the evaluation method according to the present embodiment will be described.
[0035]
In the optical fiber evaluation apparatus and the evaluation method using the optical fiber evaluation apparatus shown in FIG. 1, the deviation of the waveform from the straight line by the deviation waveform between the OTDR waveform and the approximate straight line with respect to the OTDR waveform measured by the waveform measuring unit 2. The difference value of the deviation representing the height is calculated. The abnormality of the optical fiber F is evaluated based on whether or not the calculated difference value satisfies a predetermined condition. Thereby, even if it is a normal case in view of the loss in the optical fiber, the abnormality of the optical fiber can be reliably evaluated.
[0036]
In particular, the difference value calculated from the maximum or maximum deviation value and the minimum or minimum value in the deviation waveform is used to determine the abnormality, so that the magnitude of deviation from the straight line of the waveform and the resulting light It is possible to correctly evaluate the magnitude of fiber anomalies. Further, such an evaluation method is effective for evaluating an optical fiber abnormality such as a deviation abnormality in a wide range. A specific method for evaluating an optical fiber abnormality using the difference value in the deviation waveform will be described later.
[0037]
Moreover, in this embodiment, when the abnormality of the optical fiber is determined by the evaluation using the difference value of the deviation, the dividing point where the abnormality can be reduced by dividing the optical fiber F is determined. . As described above, by determining a suitable dividing point of the optical fiber for an optical fiber abnormality such as a deviation abnormality in a wide range determined by the above-described method, the optical fiber in which the abnormality is determined can be improved. It becomes possible to divide and use into two or more optical fibers having characteristics.
[0038]
Further, for the division point determined for the optical fiber, the waveform is divided by the division point, and the calculation and determination of the difference value of the deviation are repeated. Thereby, when an optical fiber is divided at the determined dividing point, it can be determined in advance whether each of the two or more optical fibers obtained by the division is an optical fiber having good characteristics.
[0039]
In addition, regarding the determination of the abnormality of the optical fiber F in the abnormality determination unit 50, the abnormality determination may be performed immediately from the determination result in the difference value determination unit 51. However, the abnormality determination using another method is additionally performed. It is also possible to use in combination.
[0040]
As such an additional abnormality determination method, for example, with respect to an OTDR waveform, a slope at each time point of the waveform is calculated, and the calculated slope value is within a predetermined range (for example, a set allowable slope range). There is a method for determining the abnormality of the optical fiber depending on whether it is in the inner). Alternatively, the waveform is divided into a plurality of sections with a predetermined section width, the slope of the section approximation straight line with respect to the waveform within the section is calculated for each of the plurality of sections, and the calculated slope value is within a predetermined range. There is a method of determining an optical fiber abnormality depending on whether it is within (for example, within a set allowable inclination range).
[0041]
In this way, in addition to the evaluation of the optical fiber abnormality using the difference value of the deviation in the deviation waveform, an evaluation method using the inclination at each time point of the waveform or the inclination of the approximate straight line in each section of the waveform is provided. By using in combination, it is possible to more reliably evaluate optical fiber abnormalities.
[0042]
An optical fiber abnormality evaluation method using the difference value of the deviation in the deviation waveform of the OTDR waveform will be described with a specific example. Here, the horizontal axis in each graph shown below represents the fiber length (position on the optical fiber F to be evaluated). This fiber length corresponds to a delay time from when the pulse light is transmitted by the pulse light transmitter 21 until the return light is received by the return light receiver 23.
[0043]
FIG. 2 is a graph showing an example of (a) an OTDR waveform and an approximate line, (b) a deviation waveform, and (c) a time change in the slope of the waveform.
[0044]
In this example, as shown in FIG. 2 (a), for an optical fiber having a predetermined total fiber length L (for example, L = 50 km), the OTDR has different values of inclination at the substantially central point P as a boundary. An example of a waveform (solid line) is shown. An approximate straight line (broken line) can be obtained by applying an approximate method such as a least square method to this waveform. Note that the slope of the waveform or approximate line corresponds to the loss at each position of the optical fiber. The average loss due to the slope of the approximate line is, for example, about 0.200 dB / km.
[0045]
With respect to these waveforms and approximate lines, a deviation waveform is obtained from the deviation due to the difference between the value of the waveform at each position and the value of the approximate line. And in this deviation waveform, the difference value which shows the magnitude | size of the deviation in a waveform is calculated. In the example of the deviation waveform shown in FIG. 2B, the points A at both ends of the deviation waveform. ₁ , A ₂ Each has a maximum deviation. At this time, point A ₁ , A ₂ The deviation at is the first reference value in the difference value calculation. Further, the deviation is the minimum (minimum) at a point B corresponding to the point P at the approximate center of the deviation waveform. At this time, the deviation at the point B becomes the second reference value. Then, a difference value Δs (for example, Δs = 0.1 dB) in the deviation waveform is obtained by the difference between the first reference value and the second reference value.
[0046]
On the other hand, with respect to the difference value Δs in the deviation waveform, an allowable deviation range is set in advance as an allowable numerical range as an allowable condition for the difference value of deviation. Then, the calculated difference value Δs is compared with the allowable deviation range, and if the difference value is outside the allowable deviation range, such as when the difference value Δs is larger than the allowable upper limit, it is determined that there is a deviation abnormality in the optical fiber. To do. According to such an optical fiber evaluation method, it is possible to reliably determine an abnormality even with respect to a deviation abnormality in a wide range as shown in the waveform of FIG.
[0047]
Also, the graph of FIG. 2C shows the OTDR waveform shown in FIG. 2A and the slope of the approximate line. In this graph, the broken line indicates the average slope value of the entire waveform obtained from the approximate straight line. This corresponds to the average loss of the entire optical fiber having the fiber length L that is the object of evaluation. The solid line indicates the change in the slope value at each position of the waveform. This corresponds to a change in loss at each position of the optical fiber. In this example, the slope value indicated by the solid line changes stepwise with the point P at the substantially center of the optical fiber as a boundary.
[0048]
Here, in the optical fiber in which the OTDR waveform shown in FIG. 2A is obtained, two optical fibers having substantially different cores are connected at a point P due to a core variation at the time of manufacture. The structure is equal to the state. In such an optical fiber, the core diameter changes at the point P in the optical fiber as a boundary, and accordingly, the loss in the optical fiber and the effective area A of the core A _eff Characteristic values such as mode field diameter and dispersion change. FIG. 2C shows a stepwise change in the loss value at the point P as an example.
[0049]
In the evaluation of such an optical fiber, an approximate straight line is obtained for the OTDR waveform, and the loss in the optical fiber is calculated from the slope thereof. Loss is determined as an apparent loss value. Similarly, when characteristics such as dispersion other than loss are evaluated, averaged apparent characteristic values are obtained. With respect to the optical fiber whose average characteristic has been evaluated, when two optical fibers of 25 km are created by dividing the total fiber length of 50 km into two, the two optical fibers after the division are apparent from FIG. Thus, it has a characteristic different from the characteristic value evaluated in the optical fiber before the division.
[0050]
For example, considering the case where an optical fiber whose average dispersion has been evaluated before division is divided into two optical fibers and dispersion compensation is performed for each of them, dispersion based on the value of average dispersion before division is considered. In the compensation, the dispersion of the divided optical fiber is not correctly compensated. On the other hand, in a wavelength division multiplexing (WDM) transmission system that has been developed and used for the purpose of high-speed and large-capacity optical transmission in recent years, the occurrence of nonlinear phenomena should be suppressed to prevent information degradation. The amount of information that can be transmitted is increased. On the other hand, if the chromatic dispersion in the optical transmission is not sufficiently compensated, the transmission characteristic of the signal light is deteriorated.
[0051]
On the other hand, according to the above-described evaluation method for detecting anomalies in the optical fiber by detecting deviation anomalies from the waveform and the approximate straight line, even for abnormalities in which the characteristic value changes in the middle of the optical fiber, A reliable evaluation is possible.
[0052]
Here, as a specific method of deriving the first reference value and the second reference value from the deviation waveform and calculating the difference value of the deviation, there are two types, for example, a method using data points and a method using sections. The method can be used.
[0053]
FIG. 3 is a graph showing a method of calculating a difference value of deviation by (a) data points and (b) intervals of the deviation waveform.
[0054]
First, in the method of calculating the difference value by the data points of the deviation waveform, as shown in FIG. 3A, the first reference point A having the maximum or maximum deviation from the plurality of data points in the deviation waveform, and the deviation And the second reference point B at which is minimum or minimum. The deviation value at the first reference point A is the first reference value, the deviation value at the second reference point B is the second reference value, and the deviation from the difference between the first reference value and the second reference value is determined. The difference value Δs is calculated. According to such a method, the deviation waveform can be reproduced in detail, and the position of the abnormal point of the optical fiber can be accurately determined.
[0055]
Further, in the method of calculating the difference value by the section of the deviation waveform, as shown in FIG. 3B, the deviation waveform is divided into a plurality of sections with a predetermined section width T in advance, and the deviation is averaged for each section. The first reference section T having a maximum or maximum deviation from the plurality of sections. _A And the second reference interval T in which the deviation is minimized or minimized. _B And detect. And the first reference section T _A The deviation value at the first reference value, the second reference interval T _B The deviation value at is used as the second reference value, and the difference value Δs of the deviation is calculated from the difference between the first reference value and the second reference value. According to such a method, it is possible to reliably determine the abnormality of the optical fiber by reducing the influence of minute fluctuations such as noise on the deviation waveform.
[0056]
Next, a method for evaluating an additional abnormality of the optical fiber using the slope of the OTDR waveform will be described.
[0057]
In the optical fiber evaluation method described above, an approximate straight line is obtained for the OTDR waveform (FIG. 2 (a)), and a deviation waveform between the waveform and the approximate straight line is calculated (FIG. 2 (b)). And abnormality of an optical fiber is determined from the difference value in the calculated deviation waveform. On the other hand, it is possible to determine abnormality in various patterns by performing additional abnormality evaluation using the slope of the OTDR waveform.
[0058]
FIG. 2C is a graph showing the slope of the OTDR waveform corresponding to the loss in the optical fiber. As described above, the slope changes stepwise with the point P as the boundary. In the evaluation of abnormality using the inclination of the waveform, an allowable inclination range (allowable loss range) is set in advance with respect to the value of the inclination (loss) using an average inclination on an approximate line as a reference value. Then, the calculated inclination value is compared with the allowable inclination range, and if the inclination value is outside the allowable inclination range, it is determined that the optical fiber has an inclination abnormality (loss abnormality).
[0059]
In contrast to the evaluation of deviation abnormality that is determined based on the relative value, in the evaluation of inclination abnormality, the abnormality can be determined based on the absolute value. Such an evaluation method is effective for determining a local abnormality or a segmental abnormality. Therefore, if these evaluation methods are used in combination, abnormality in various patterns can be determined. As a specific numerical value, for example, with respect to the average loss of 0.200 dB / km obtained from the approximate straight line, the average loss is set as a reference value, and 0.150 to 0.250 dB / km is set as the allowable loss range. On the other hand, if the fluctuation of the loss obtained from the OTDR waveform is in the range of 0.190 to 0.210 dB / km, it is determined that there is no loss abnormality as being within the allowable loss range.
[0060]
As a method of calculating the inclination of the waveform in the evaluation method for determining such an inclination abnormality, there is a method of calculating the inclination from the data points at each time point of the waveform. In this case, the slope value is obtained from the difference between adjacent data points in the waveform. Alternatively, there is a method in which the waveform is divided into a plurality of sections, a section approximate straight line is obtained for each section, and the slope of the section approximate straight line is calculated as the slope of the waveform. In this case, the slope value is obtained for each section.
[0061]
Note that the evaluation method using the slope value of the waveform and the approximate straight line is more susceptible to minute fluctuations such as noise in the waveform than the evaluation method using the difference value of the deviation. Accordingly, it is preferable to evaluate the abnormality of the optical fiber by combining the determination of the deviation abnormality and the determination of the inclination abnormality (loss abnormality) while taking into consideration the influence of such minute fluctuations.
[0062]
Examples of a combination method for determining deviation abnormality and inclination abnormality include the following methods. First, when both the deviation and the inclination are normal, it is determined that the optical fiber is normal. When the deviation is abnormal and the inclination is normal, a dividing point is determined for the optical fiber. When the deviation is normal and the slope is abnormal, the local abnormality is regarded as abnormal as it is, and if the section is abnormal, it is determined as an erroneous determination due to noise and normal. If both the deviation and the inclination are abnormal, it is determined that the optical fiber is abnormal. Moreover, you may combine determination of deviation abnormality and inclination abnormality by methods other than this.
[0063]
Next, a method for determining the dividing point of the optical fiber and a method for re-evaluating the optical fiber when the dividing point is determined will be described.
[0064]
FIG. 4 is a graph showing an example of temporal changes in (a) an OTDR waveform and an approximate line, (b) a deviation waveform, (c) a divided deviation waveform in the first half part, and (d) a deviation waveform in the second half part. .
[0065]
In this example, as shown in FIG. 4A, for an optical fiber having a fiber length L to be evaluated, an OTDR waveform whose waveform slope gradually decreases from the first half portion toward the second half portion. An example is shown. When such a waveform is obtained, the deviation waveform shown in FIG. 4B obtained from the waveform and the approximate straight line is referred to, and the point D at which the deviation is minimized is determined as the division point of the optical fiber. Can do. According to the division point D determined in this way, an optical fiber having a fiber length L having a large difference value Δs is changed to a fiber length L having a large inclination. ₁ Fiber length L with a small inclination ₂ It can be divided into two optical fibers with the latter half part.
[0066]
When the division point D is determined in this way, the light obtained by dividing the OTDR waveform by dividing the division point D and repeatedly calculating and determining the difference value of the deviation for each waveform. Each characteristic of the fiber can be determined in advance.
[0067]
That is, as shown in FIG. ₁ First half and fiber length L ₂ For the latter half of the part, a reapproximation straight line is obtained from the waveform at each part. Then, from the difference between the waveform and the reapproximation straight line, the deviation waveform of the first half portion (FIG. 4C) and the deviation waveform of the second half portion (FIG. 4D) when divided at the division point D are obtained, respectively. From the difference value in the deviation waveform, an optical fiber abnormality after division is determined.
[0068]
In these determination results, if the difference values of the respective deviations satisfy the allowable conditions, it can be determined that two normal optical fibers can be obtained by dividing the optical fiber at the dividing point D. In addition to the determination of abnormal deviation using the difference value of the deviation for the waveform of the first half and the second half corresponding to the optical fiber after these divisions, the loss abnormality using the slope of the waveform or the interval approximation line is used. The determination may be further performed.
[0069]
In the above example, the minimum point of deviation is set as the dividing point D as shown in FIG. 4B, but the dividing point is determined by another method according to the shape of each waveform. A point may be determined. For example, when an OTDR waveform is obtained in which the slope of the waveform gradually increases from the first half portion toward the second half portion, the maximum point of deviation in the deviation waveform can be used as a division point.
[0070]
Further, when there is a range in which the waveform deviation and inclination change rapidly in the vicinity of the dividing point D, when the optical fiber is divided, a predetermined range in the vicinity of the dividing point D (for example, as shown in FIG. 4B). Fiber length L _Three Is preferably discarded.
[0071]
The optical fiber evaluation method and the evaluation apparatus according to the present invention are not limited to the above-described embodiments and examples, and various modifications are possible. For example, in the optical fiber evaluation apparatus 1 shown in FIG. 1, a configuration in which a waveform measurement section 2 that is an OTDR measurement apparatus is added to a waveform evaluation section 3 that evaluates an abnormality of an optical fiber using an OTDR waveform. However, the measurement device may be a separate device, and the optical fiber may be evaluated by reading the data of the OTDR waveform measured by the measurement device. Further, in the case where it is necessary to evaluate only the abnormality of the optical fiber, it may be configured such that determination of the dividing point of the optical fiber and re-evaluation of the optical fiber after the division are not performed.
[0072]
【The invention's effect】
As described in detail above, the optical fiber evaluation method and the evaluation apparatus according to the present invention obtain the following effects. That is, an evaluation method for calculating a difference value of a deviation representing a deviation from a straight line of a waveform based on a deviation waveform between an OTDR waveform and an approximate straight line, and determining an optical fiber abnormality depending on whether or not the difference value satisfies a predetermined condition. According to the evaluation apparatus, it is possible to reliably evaluate optical fiber abnormality such as deviation abnormality in a wide range. In particular, by using the difference value calculated from the maximum value or maximum value of the deviation and the minimum value or minimum value for determining an abnormality, it is possible to correctly evaluate the magnitude of deviation from the straight line of the waveform. .
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of an optical fiber evaluation apparatus.
FIGS. 2A and 2B are graphs showing an example of a temporal change in (a) an OTDR waveform and an approximate line, (b) a deviation waveform, and (c) a slope of the waveform.
FIG. 3 is a graph showing a method of calculating a difference value of deviation by (a) data points and (b) intervals of a deviation waveform;
FIGS. 4A and 4B are graphs showing an example of a temporal change of an OTDR waveform and an approximate line, (b) a deviation waveform, (c) a divided deviation waveform in the first half part, and (d) a deviation waveform in the second half part. .
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Optical fiber evaluation apparatus, F ... Optical fiber, 2 ... Waveform measurement part, 20 ... Measurement control part, 21 ... Pulse light transmission part, 22 ... Optical coupler, 23 ... Return light reception part, 24 ... Signal processing part, 3 DESCRIPTION OF SYMBOLS ... Waveform evaluation part, 4 ... Calculation part, 40 ... Waveform generation part, 41 ... Approximate straight line calculation part, 42 ... Deviation waveform calculation part, 43 ... Difference value calculation part, 44 ... Waveform division part, 5 ... Determination part, 50 ... Abnormality determination unit, 51 ... difference value determination unit, 52 ... division point determination unit.

Claims (6)

An evaluation method for evaluating the optical fiber by detecting a return light power from the optical fiber by injecting pulsed light into the optical fiber to be evaluated, and measuring a waveform of the return light power with respect to time,
An approximate straight line calculating step for obtaining an approximate straight line for the portion of the waveform to be evaluated;
A deviation waveform calculating step for obtaining a deviation waveform from a difference between the portion to be evaluated of the waveform and the approximate straight line;
A difference value for calculating a difference value between the first reference value and the second reference value by obtaining a first reference value at which the deviation is maximized or maximized and a second reference value at which the deviation is minimized or minimized. A calculation step;
Whether or not the difference value satisfies a predetermined condition, a difference value determination step for determining abnormality of the optical fiber ,
A split point determining step of determining a split point at which the fault can be reduced by splitting the optical fiber when an abnormality of the optical fiber is determined. Fiber evaluation method.   2. The optical fiber evaluation method according to claim 1, wherein, in the difference value calculating step, the deviation waveform is divided into a plurality of sections with respect to time in advance, and the difference is averaged for each section. A waveform dividing step of dividing the waveform by the dividing points;
For each of the divided said waveform, said approximate straight line calculating step, the the difference waveform calculation step, and the difference value calculation step, the optical fiber according to claim 1, characterized in that the said difference value determining step Evaluation methods.   An abnormality determination step of calculating an inclination at each time point of the waveform and determining an abnormality of the optical fiber depending on whether or not the calculated value of the inclination is within a predetermined range. 2. The optical fiber evaluation method according to 1.   The waveform is divided into a plurality of sections with a predetermined section width, and for each of the plurality of sections, a section approximation line for the waveform within the section is obtained, and the value of the slope of the section approximation line is predetermined. The optical fiber evaluation method according to claim 1, further comprising: an abnormality determination step of determining an abnormality of the optical fiber depending on whether or not the optical fiber is within the range. An evaluation device that evaluates the optical fiber by detecting a return light power from the optical fiber by inputting pulsed light into the optical fiber to be evaluated, and measuring a waveform of the return light power with respect to time,
An approximate straight line calculating means for obtaining an approximate straight line for a portion of the waveform to be evaluated;
Deviation waveform calculation means for obtaining a deviation waveform from the difference between the portion to be evaluated of the waveform and the approximate straight line;
A difference value for calculating a difference value between the first reference value and the second reference value by obtaining a first reference value at which the deviation is maximized or maximized and a second reference value at which the deviation is minimized or minimized. A calculation means;
Whether or not the difference value satisfies a predetermined condition, difference value determination means for determining an abnormality of the optical fiber ,
Splitting point determining means for determining a splitting point capable of reducing the fault by splitting the optical fiber when an abnormality of the optical fiber is determined. Fiber evaluation device.

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